| Literature DB >> 33129188 |
Mireille M J P E Sthijns1, Marlon J Jetten1, Sami G Mohammed1, Sandra M H Claessen1, Rick H W de Vries1, Adam Stell1, Denise F A de Bont1, Marten A Engelse2, Didem Mumcuoglu3, Clemens A van Blitterswijk1, Patricia Y W Dankers3, Eelco J P de Koning4, Aart A van Apeldoorn1, Vanessa L S LaPointe5.
Abstract
The clinical success rate of islet transplantation, namely independence from insulin injections, is limited by factors that lead to graft failure, including inflammation, acute ischemia, acute phase response, and insufficient vascularization. The ischemia and insufficient vascularization both lead to high levels of oxidative stress, which are further aggravated by islet encapsulation, inflammation, and undesirable cell-biomaterial interactions. To identify biomaterials that would not further increase damaging oxidative stress levels and that are also suitable for manufacturing a beta cell encapsulation device, we studied five clinically approved polymers for their effect on oxidative stress and islet (alpha and beta cell) function. We found that 300 poly(ethylene oxide terephthalate) 55/poly(butylene terephthalate) 45 (PEOT/PBT300) was more resistant to breakage and more elastic than other biomaterials, which is important for its immunoprotective function. In addition, it did not induce oxidative stress or reduce viability in the MIN6 beta cell line, and even promoted protective endogenous antioxidant expression over 7 days. Importantly, PEOT/PBT300 is one of the biomaterials we studied that did not interfere with insulin secretion in human islets.Entities:
Keywords: Biomaterials; Clinical islet transplantation; Islet encapsulation device; Oxidative stress; Type 1 diabetes
Year: 2020 PMID: 33129188 DOI: 10.1016/j.biomaterials.2020.120449
Source DB: PubMed Journal: Biomaterials ISSN: 0142-9612 Impact factor: 12.479