AI Article Synopsis
- Tissue engineering for small intestine substitutes is still experimental, with most studies focusing on PLLA/PGA scaffolds but limited by in vivo experiments.
- The current research explores a new nanocomposite (POSS/PCL) to create porous scaffolds using a solvent casting technique, achieving pore sizes of 150-250 microm and porosity of 40-80%.
- Results indicate that the POSS-PCL scaffolds support the proliferation of rat intestinal epithelial cells, suggesting potential as a viable alternative to existing scaffold materials in small intestinal tissue engineering.
Article Abstract
Tissue engineering of the small intestine remains experimental despite worldwide attempts to develop a functional substitute for short bowel syndrome. Most published studies have reported predominant use of PLLA (poly-L-lactide acid)/PGA (polyglycolic acid) copolymer as the scaffold material, and studies have been limited by in vivo experiments. This lack of progress has inspired a fresh perspective and provoked further investigation and development in this field of tissue engineering. In the present paper, we exploit a relatively new nanocomposite of POSS (polyhedral oligomeric silsesquioxane) and PCL [poly(caprolactone-urea)urethane] as a material to develop porous scaffolds using a solvent casting/particulate leaching technique to fabricate porous scaffolds in different pore sizes and porosities. Scaffolds were characterized for pore morphology and porosity using scanning electron microscopy and micro-computed tomography. Rat intestinal epithelial cells were then seeded on to the polymer scaffolds for an in vitro study of cell compatibility and proliferation, which was assessed by Alamar Blue and lactate dehydrogenase assays performed for 21 days post-seeding. The results obtained demonstrate that POSS-PCL nanocomposite was produced as a macroporous scaffold with porosity over the range of 40-80% and pore size over the range of 150-250 microm. This scaffold was shown to support epithelial cell proliferation and growth. In conclusion, as a further step in investigating small intestinal tissue engineering, the nanocomposite employed in this study may prove to be a useful alternative to poly(lactic-co-glycolic acid) in the future.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2825731 | PMC |
| http://dx.doi.org/10.1042/BA20090214 | DOI Listing |
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