Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs
Tissue Engineering holds the promise to repair damaged human tissues and organs by engineering tissues in the laboratory. Usually, cells are seeded in porous scaffolds and subjected to a bioreactor for the regeneration of tissues. Unfortunately, the regenerated tissues commonly suffer from inadequat...
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2013
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sg-ntu-dr.10356-1075272020-09-27T20:29:54Z Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs Gerard, Nathanael Adrianus Chong, Chuh Khiun School of Chemical and Biomedical Engineering Tissue Engineering holds the promise to repair damaged human tissues and organs by engineering tissues in the laboratory. Usually, cells are seeded in porous scaffolds and subjected to a bioreactor for the regeneration of tissues. Unfortunately, the regenerated tissues commonly suffer from inadequate thickness and cell density. They are usually non-homogenous, thicker near the periphery but less dense near the bottom [1]. These problems make the tissue grown this way unsuitable for clinical applications. It is believed that this is due to limited diffusion of essential nutrients (most importantly oxygen) into the scaffold, which hampers tissue growth. We hypothesized that the scaffold’s structural properties, such as void fraction, pore size distribution, degree of cross-linking influence the ability of oxygen diffusion in the scaffold. Thus, it is necessary to study oxygen diffusion profiles in scaffolds in order to design better scaffolds to enhance cellular activities and tissue quality. [4th Award] 2013-01-31T06:51:26Z 2019-12-06T22:33:16Z 2013-01-31T06:51:26Z 2019-12-06T22:33:16Z 2007 2007 Student Research Poster Gerard, N. A. (2007, March).Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs. Presented at Discover URECA @ NTU poster exhibition and competition, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/107527 http://hdl.handle.net/10220/9016 en © 2007 The Author(s). application/pdf |
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Tissue Engineering holds the promise to repair damaged human tissues and organs by engineering tissues in the laboratory. Usually, cells are seeded in porous scaffolds and subjected to a bioreactor for the regeneration of tissues. Unfortunately, the regenerated tissues commonly suffer from inadequate thickness and cell density. They are usually non-homogenous, thicker near the periphery but less dense near the bottom [1]. These problems make the tissue grown this way unsuitable for clinical applications. It is believed that this is due to limited diffusion of essential nutrients (most importantly oxygen) into the scaffold, which hampers tissue growth. We hypothesized that the scaffold’s structural properties, such as void fraction, pore size distribution, degree of cross-linking influence the ability of oxygen diffusion in the scaffold. Thus, it is necessary to study oxygen diffusion profiles in scaffolds in order to design better scaffolds to enhance cellular activities and tissue quality. [4th Award] |
| author2 |
Chong, Chuh Khiun |
| author_facet |
Chong, Chuh Khiun Gerard, Nathanael Adrianus |
| format |
Student Research Poster |
| author |
Gerard, Nathanael Adrianus |
| spellingShingle |
Gerard, Nathanael Adrianus Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| author_sort |
Gerard, Nathanael Adrianus |
| title |
Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| title_short |
Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| title_full |
Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| title_fullStr |
Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| title_full_unstemmed |
Assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| title_sort |
assessment and modeling of oxygen tension in porous structures and engineered tissue constructs |
| publishDate |
2013 |
| url |
https://hdl.handle.net/10356/107527 http://hdl.handle.net/10220/9016 |
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1681058648315396096 |