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Respiratory dysfunction induced by dust particles in inkjet bioprinted alveolar barrier

Respiratory dysfunction induced by dust particles in inkjet bioprinted alveolar barrier
Date Issued
Tissue Engineering and Regenerative Medicine International Society
The need for research to analyze the effects of dust particles on the respiratory system has been highlighted because such damage causes serious respiratory problems. However, most studies of dust toxicity have been conducted in two-dimensional cell culture, animal models, and epidemiological investigations. To find out how dust can cause respiratory problems, researchers should investigate using a reliable three-dimensional structural model that mimics human nature alveoli. In this study, dust particles were applied to the previously developed three-dimensional alveoli barrier created by the inkjet bioprinting process. As a result, we observed dramatic cell apoptosis, reduced proliferation and lung dysfunction in inkjet bioprinted alveolar barriers exposed to dust particles. We also observed an increase in pro-inflammatory cytokines that stimulated the secretion of matrix metalloproteinase (MMP). To analyze the effect of increasing immune response from dust, dust was treated in dose- and time-dependent manner and alveolar tissue collapse was identified to induce structural collapse and reduced barrier robustness. We further investigated lung surfactant protein related genes in dust-treated alveoli tissues and then estimate the harmful effects of dust on lung surfactant dysfunction. This study demonstrated the physiological effects of dust on cytotoxicity, alveolar barrier stiffness and surfactant secretion at gene expression level using inkjet bioprinted alveoli barriers. It has also been demonstrated that dust can have serious consequences that can lead to the collapse of the alveoli barrier. Using in vitro inkjet bio-printed 3D alveoli barriers, we expect this strategy to be a useful tool for identifying air pollutant exposure-related diseases
Article Type
Tissue Engineering and Regenerative Medicine International Society - 6th World Congress (TERMIS-WC 2021), 2021-11-16
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Dept of Materials Science & Enginrg
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