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KIM, DONG SUNG (김동성)
Dept of Mechanical Engineering(기계공학과)
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SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic development:1||Enzymatic Degradation:1||limbal stem cell deficiency (LSCD):1||Gene expression:1||RECOVERY:1||FILMS:1||CULTURE:1||MICROENVIRONMENTS:1||CUES:1||Dip coating:1||METAL COMPOSITES:1||STROMAL CELLS:1||Transverse secondary flows:1||ALGINATECHITOSAN:1||WETTING TRANSITION:1||LOTUS:1||DROPS:1||OXIDE MOLD:1||RANDOMIZEDTRIAL:1||Chemistry:1||hydrogel:1||Immune response:1||Real time visualization:1||Article:1||cell infiltration:1||cell interaction:1||endothelium cell:1||leukocyte infiltration:1||macrophage:1||T cell tissue infiltration:1||Composite materials:1||SCAFFOLDFREE:1||SCAFFOLD:1||MURINE:1||polymer replication:1||NANOCOMPOSITES:1||CLINICAL DIAGNOSTICS:1||Noncontamination:1||Dispensing system:1||Highspeedsolenoid valve:1||Portable pressure pump:1||Microfluidic labonachip:1||Porous PDMS sponge:1||ARRAYS:1||LAB:1||3Dimensional focusing:1||Silver electrode:1||Selective microfabrication:1||SEPARATION:1||centrifugal force:1||modeling:1||ECG:1||NANOWIRES:1||Liquids:1||Potassium compounds:1||Controlled deposition:1||Conventional metals:1||Low salt concentration:1||Electrolyte solutions:1||perivascular macrophage:1||T lymphocyte activation:1||Aspect ratio:1||Stem cells:1||X ray lithography:1||MODEL:1||FILLING FLOW:1||EMBOLIZATION:1||Plastic labonadisk:1||CD:1||Microlens:1||ELECTROPHORESIS:1||Pressure driven flow:1||GRAVITY:1||THERMOPLASTIC POLYMERS:1||RESIDUALSTRESSES:1||MICROLENS ARRAYS:1||DRY ELECTRODES:1||PARTICLES:1||poly(Nisopropylacrylamide):1||phase separation of supersaturated Nisopropylacrylamide:1||Electric fields:1||Electrolytes:1||Electrospun nanofibers:1||Three dimensional computer graphics:1||Nanofiber membrane:1||Tissue inflammation:1||Blood vessels:1||electrospinning:1||Nanopores:1||Pathological process:1||Surface reconstruction:1||Transplantation (surgical):1||Seeding efficiency:1||DETACHMENT:1||NANOTOPOGRAPHY:1||SYMMETRY:1||GROWTH:1||POLYMER PARTICLES:1||Centrifugal microfluidics:1||WHOLEBLOOD:1||Mixing:1||MICROCAPSULES:1||CONTROLLEDRELEASE:1||SURFACE:1||REPLICATION:1||microendmilling:1||EMULSIONS:1||Electrospinning:1||Deposition:1||Line arrays:1||Microenvironments:1||biochemistry:1||human:1||Pore size:1||High aspect ratio:1||Biocomposites:1||Fibrillar structures:1||Long term stability:1||Enzyme activity:1||Environmental cues:1||LINEAGE:1||cell adhesion:1||INVITRO:1||BIOCHIP:1||STATE:1||MICROFLUIDIC PLATFORMS:1||CULTURES:1||GOLD NANOPARTICLES:1||PORES:1||UV curable resin:1||BIREFRINGENCE:1||analysis:1||microneedle array:1||TIO2 NANOFIBERS:1||FILM:1||Membranes:1||Micro fluidic system:1||Versatile tools:1||nanofiber:1||Adhesion:1||Cytology:1||Research fields:1||Cell signaling:1||corneal lenticule:1||Coatings:1||Morphological analysis:1||Muscle:1||INVIVO:1||FLOW:1||Biomimetic actuator:1||PROLIFERATION:1||adiposederived stem cell:1||CHAMBER:1||Microfluidics:1||MICROFLUIDICS:1||Biochemical assay:1||CHIP APPLICATIONS:1||Polydimethylsiloxane (PDMS):1||Overflow:1||Locally increased aspect ratio:1||PARAMETERS:1||SHRINKAGE:1||electropolishing:1||transient filling flow:1||surface electromyography:1||EEG:1||Janus particle:1||Issue 108:1||MEMBRANES:1||Spinning (fibers):1||Nanofiber mats:1||Dielectric liquids:1||Biochemical effects:1||matrigel:1||controlled study:1||human cell:1||Center distance:1||Focal adhesion kinase:1||Focal adhesions:1||Cell culture:1||Corneal epithelial cells:1||Corneal refractive surgery:1||Myogenic differentiations:1||Surface wettability:1||SYSTEMS:8||FABRICATION:8||ADHESION:7||MIXER:6||MICROPUMP:6||LITHOGRAPHY:6||TOTAL ANALYSIS SYSTEMS:5||SUBSTRATE:4||MICROCHANNELS:4||DIFFERENTIATION:4||Hot embossing:4||MORPHOLOGY:3||FLOWS:3||MICROCHANNEL:3||SURFACES:3||ADVECTION:3||ROUGH SURFACES:3||WETTABILITY:3||Deep Xray lithography:3||SERPENTINE LAMINATING MICROMIXER:3||MIGRATION:3||STEMCELLS:3||Extracellular matrices:2||SCAFFOLDS:2||ROUGHNESS:2||NANOSCALE:2||WATERREPELLENT:2||CREATION:2||replication quality:2||Microchannel:2||Tissue:2||Polyurethane mold:2||Cell aggregates:2||TITANIUM:2||SUPERHYDROPHOBIC SURFACE:2||DROPLETS:2||chaotic advection:2||SILICON:2||LAYER:2||Nickel mold insert:2||TECHNOLOGY:2||RESIST:2||EXTRACELLULARMATRIX:2||MOVEMENT:2||DEVICES:2||replication measure:2||FRACTAL STRUCTURE:2||CHIP:2||CARBONATEBASED PREPOLYMERS:2||Nanofibers:2||Tissue regeneration:2||FORCE:2||MICROFLUIDIC DEVICES:2||TOPOGRAPHY:2||SUPER:2||microfilter:2||microfluidics:2||Polystyrene:2||OSTEOBLASTLIKE CELLS:2||lamination:2||SYSTEM:2||MICROSTRUCTURES:2||alginate:2||agarose:2||microchannel:2||DEVICE:2||Microchamber/nanodimple (MCND):2||Microindented nanodimpleanodic aluminum oxide (MNAAO):2||TOOLS:2||hydrophobicity:2||microinjection molding:2||SIMULATION:2||Microfluidic device:2||scaffold:2||HIERARCHICAL NANOSTRUCTURES:2||Taguchi method:2||MICRO:2||UVnanoimprint lithography (UVNIL):2||plant leaf:2||labonachip:2||microfluidic system:2||micromixer:2||WATER:2||ORIENTATION:2||PLASMA:2||cartilage:2||bioreactor:2||Graphene nanocomposite:1||Ionic polymer:1||TISSUE:1||lotus leaf surface structure:1||DISPERSION:1||Magnetohydrodynamics (MHD):1||DESIGN:1||MICROMIXERS:1||Sugar leaching technique:1||MEMBRANE:1||Labonachip:1||MICROFLUIDIC SYSTEMS:1||GRAVITAXIS:1||nanopillar array:1||curved electrode:1||anisotropic thermoresponsiveness:1||Cells:1||Collagen:1||Polystyrenes:1||Multinucleated myotubes:1||POLYMER BRUSHES:1||STIFFNESS:1||stem cell differentiation:1||Complex flow:1||Computational fluid dynamics (CFD):1||Design methodology:1||Coriolis force:1||MICROSPHERES:1||Hydrodynamic focusing:1||CASSIE:1||Multiphase laminar flow:1||CHIPS:1||AMORPHOUS POLYMERS:1||PERFORMANCE:1||anodic aluminum oxide (AAO):1||ADHESIVE:1||organophilic/hydrophilic loading capability:1||DYNAMICS:1||FIBERS:1||electrolyte assisted electrospinning with site selective surface modification:1||membrane structure:1||nanofabrication:1||priority journal:1||Chemical activation:1||Embryonic d
