The Effects of Dynamic Culturing Environments on Cell Populations Relevant to Heart Valve Tissue Engineering
The design of a tissue engineered pulmonary valve (TEPV) involves cells source(s), scaffold, in vitro conditioning system and the functional stability of the TEPV in vivo. Vascular cells (pulmonary artery smooth muscle (SMCs) and endothelial cells (ECs)) and periodontal ligament derived stem cells (...
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| Format: | Others |
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FIU Digital Commons
2011
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| Online Access: | http://digitalcommons.fiu.edu/etd/505 http://digitalcommons.fiu.edu/cgi/viewcontent.cgi?article=1614&context=etd |
| Summary: | The design of a tissue engineered pulmonary valve (TEPV) involves cells source(s), scaffold, in vitro conditioning system and the functional stability of the TEPV in vivo. Vascular cells (pulmonary artery smooth muscle (SMCs) and endothelial cells (ECs)) and periodontal ligament derived stem cells (PDLSCs) are relevant sources for the designing of TEPVs. In this study, labeling of these cell populations with super paramagnetic iron oxide microparticles along with concomitant usage of transfection agents was followed by visualization using magnetic resonance, while Intracellular iron oxide was confirmed by prussian blue staining and fluorescence microscopy. Also, the potential of PDLSC as a feasible source for TEPVs was investigated, expressing differentiative capacity to both SMC and EC phenotypes by a combination of biochemical and mechanical stimulation. Flow conditioning in a u-shaped bioreactor augmented collagen production in SMC-EC (99.5% for n=3) and PDLSC (93.3% for n=3) seeded scaffolds after a 3-week culturing period (P<0.05). |
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