Collagen and Endothelial Cell Coculture Improves ß-Cell Functionality and Rescues Pancreatic Extracellular Matrix.

The use of biomaterials and biomaterial functionalization is a promising approach to support pancreatic islet viability posttransplantation in an effort to reduce insulin dependence for patients afflicted with diabetes mellitus type 1. Extracellular matrix (ECM) proteins are known to impact numerous reparative functions in the body. Assessing how endogenously expressed pancreatic ECM proteins are affected by posttransplant-like hypoxic conditions may provide significant insights toward the development of tissue-engineered therapeutic strategies to positively influence ß-cell survival, proliferation, and functionality. Here, we investigated the expression of three relevant groups of pancreatic ECM proteins in human native tissue, including basement membrane (BM) proteins (collagen type 4 [COL4], laminins [LAM]), proteoglycans (decorin [DCN], nidogen-1 [NID1]), and fibril-forming proteins (fibronectin [FN], collagen type 1 [COL1]). In an in vitro hypoxia model, we identified that ECM proteins were differently affected by hypoxic conditions, contributing to an overall loss of ß-cell functionality. The use of a COL1 hydrogel as carrier material demonstrated a protective effect on ß-cells mitigating the effect of hypoxia on proteoglycans as well as fibril-forming protein expression, supporting ß-cell functionality in hypoxia. We further showed that providing endothelial cells (ECs) into the COL1 hydrogel improves ß-cell response as well as the expression of relevant BM proteins. Our data show that ß-cells benefit from a microenvironment composed of structure-providing COL1 with the incorporation of ECs to withstand the harsh conditions of hypoxia. Such hydrogels support ß-cell survival and can serve as an initial source of ECM proteins to allow cell engraftment while preserving cell functionality posttransplantation. Impact statement Expression analysis identifies hypoxia-induced pathological changes in extracellular matrix (ECM) homeostasis as potential targets to support ß-cell transplants by encapsulation in biomaterials for the treatment of diabetes mellitus. A collagen-1 hydrogel is shown to attenuate the effect of hypoxia on ß-cells and their ECM expression. The functionalization of the hydrogel with endothelial cells increases the ß-cell response to glucose and rescues essential basement membrane proteins.

Fluorescence lifetime metabolic mapping of hypoxia-induced damage in pancreatic pseudo-islets.

Pancreatic islet isolation from donor pancreases is an essential step for the transplantation of insulin-secreting ß-cells as a therapy to treat type 1 diabetes mellitus. This process however damages islet basement membranes, which can lead to islet dysfunction or death. Posttransplantation, islets are further stressed by a hypoxic environment and immune reactions that cause poor engraftment and graft failure. The current standards to assess islet quality before transplantation are destructive procedures, performed on a small islet population that does not reflect the heterogeneity of large isolated islet batches. In this study, we incorporated fluorescence lifetime imaging microscopy (FLIM) into a pancreas-on-chip system to establish a protocol to noninvasively assess the viability and functionality of pancreatic ß-cells in a three-dimensional in vitro model (= pseudo-islets). We demonstrate how (pre-) hypoxic ß-cell-composed pseudo-islets can be discriminated from healthy functional pseudo-islets according to their FLIM-based metabolic profiles. The use of FLIM during the pretransplantation pancreatic islet selection process has the potential to improve the outcome of ß-cell islet transplantation.