The incorporation of extracellular matrix proteins in protein polymer hydrogels to improve encapsulated beta-cell function.

Biomaterial encapsulation of islets has been proposed to improve the long-term success of islet transplantation by recreating a suitable microenvironment and enhancing cell-matrix interactions that affect cellular function. Protein polymer hydrogels previously showed promise as a biocompatible scaffold by maintaining high cell viability. Here, enzymatically-crosslinked protein polymers were used to investigate the effects of varying scaffold properties and of introducing ECM proteins on the viability and function of encapsulated MIN6 ß-cells. Chemical and mechanical properties of the hydrogel were modified by altering the protein concentrations while collagen IV, fibronectin, and laminin were incorporated to reestablish cell-matrix interactions lost during cell isolation. Rheology indicated all hydrogels formed quickly, resulting in robust, elastic hydrogels with Young's moduli similar to soft tissue. All hydrogels tested supported both high MIN6 ß-cell viability and function and have the potential to serve as an encapsulation platform for islet cell delivery in vivo.

Protein polymer hydrogels: effects of endotoxin on biocompatibility.

Protein polymer-based hydrogels have shown potential for tissue engineering applications, but require biocompatibility testing for in vivo use. Enzymatically crosslinked protein polymer-based hydrogels were tested in vitro and in vivo to evaluate their biocompatibility. Endotoxins present in the hydrogel were removed by Trition X-114 phase separation. The reduction of endotoxins decreased TNF-α production by a macrophage cell line in vitro; however, significant inflammatory response was still present compared to collagen control gels. A branched PEG molecule and dexamethasone were added to the hydrogel to reduce the response. In vitro testing showed a decrease in the TNF-α levels with the addition of dexamethasone. In vivo implantations into the epididymal fat pad of C57/BL6 mice, however, indicated a decreased inflammatory mediated immune response with a hydrogel treated with both PEGylation and endotoxin reduction. This study demonstrates the importance of endotoxin testing and removal in determining the biocompatibility of biomaterials.

Enhanced function of pancreatic islets co-encapsulated with ECM proteins and mesenchymal stromal cells in a silk hydrogel.

Pancreatic islet encapsulation within biosynthetic materials has had limited clinical success due to loss of islet function and cell death. As an alternative encapsulation material, a silk-based scaffold was developed to reestablish the islet microenvironment lost during cell isolation. Islets were encapsulated with ECM proteins (laminin and collagen IV) and mesenchymal stromal cells (MSCs), known to have immunomodulatory properties or to enhance islet cell graft survival and function. After a 7 day in vitro encapsulation, islets remained viable and maintained insulin secretion in response to glucose stimulation. Islets encapsulated with collagen IV, or laminin had increased insulin secretion at day 2 and day 7, respectively. A 3.2-fold synergistic improvement in islet insulin secretion was observed when islets were co-encapsulated with MSCs and ECM proteins. Furthermore, encapsulated islets had increased gene expression of functional genes; insulin I, insulin II, glucagon, somatostatin, and PDX-1, and lower expression of the de-differentiation genes cytokeratin 19 and vimentin compared to non-encapsulated cells. This work demonstrates that encapsulation in silk with both MSCs and ECM proteins enhances islet function and with further development may have potential as a suitable platform for islet delivery in vivo.