Microwell scaffolds using collagen-IV and laminin-111 lead to improved insulin secretion of human islets

Intrahepatic islet transplantation is a promising therapy for treatment of type 1 diabetes. During islet isolation, collagenase is used to extract islets from the pancreas, leading to loss of important cell-matrix interactions. Loss of the native pancreatic microenvironment is associated with apoptosis of islet cells, early graft failure, and poor islet function. The islet extracellular matrix (ECM) is composed of a specific combination of collagen (Col), laminin (LN), and fibronectin (FN) molecules. Reintroducing these molecules has been shown to boost the function, viability, morphology, and proliferation of v-cells. In this research, the effect of combinatorial ECM on islet function and survival was investigated. Specifically, thin-film microwell array scaffolds made from two distinct biomaterials were coated with FN, collagen type IV (Col4), LN111, LN332, or a combination thereof. We found that coatings containing a single type of ECM molecule, for example, FN or Col, can improve short-term islet function. However, these single proteins do not prevent loss of morphology and subsequent loss of islet function afterward. In contrast, combining Col4 with LN111 at a ratio of 8:2 not only improved short-term islet function but also preserved islet structure and islet function on a longer term. This effect was reproducibly shown on poly(ester-urethane) and poly(ethylene-glycol-terephthalate-poly(butylene-terephthalate) microwell islet delivery devices as well as tissue culture polystyrene. We concluded that biofunctionalization of inert biomaterials regardless of their molecular composition with a specific combination of islet ECM molecules can support and improve islet function over longer time periods. Our data suggested that creating a biomimetic islet niche by biofunctionalization of biomaterials can significantly improve the endocrine function of v-cells. The creation of islet mimicking niches in islet delivery devices leads to an improvement of islet function by restoring part of the islet's ECM in these devices.