ABSTRACT
Three-dimensional (3D) multicellular organoids recapitulate the native complexities of human tissue better than traditional cellular monolayers. As organoids are insufficiently supported using standard static culture, microphysiological systems (MPSs) provide a key enabling technology to maintain organoid physiology in vitro. Here, a polydimethylsiloxane-free MPS that enables continuous dynamic culture and serial in situ multiparametric assessments was leveraged to culture organoids, specifically human and rodent pancreatic islets, within a 3D alginate hydrogel. Computational modeling predicted reduced hypoxic stress and improved insulin secretion compared to static culture. Experimental validation via serial, high-content, and noninvasive assessments quantitatively confirmed that the MPS platform retained organoid viability and functionality for at least 10 days, in stark contrast to the acute decline observed overnight under static conditions. Our findings demonstrate the importance of a dynamic in vitro microenvironment for the preservation of primary organoid function and the utility of this MPS for in situ multiparametric assessment.
ABSTRACT
Organ-on-a-chip platforms serve as cost-efficient testbeds for screening pharmaceutical agents, mimicking natural physiology, and studying disease. In the field of diabetes, the development of an islet-on-a-chip platform would have broad implications in understanding disease pathology and discovering potential therapies. Islet microphysiological systems are limited, however, by their poor cell survival and function in culture. A key factor that has been implicated in this decline is the disruption of islet-matrix interactions following isolation. Herein, we sought to recapitulate the in vivo peri-islet niche using decellularized extracellular matrix (ECM) hydrogels. Sourcing from porcine bladder, lung, and pancreas tissues, 3-D ECM hydrogels were generated, characterized, and validated using both rodent and human pancreatic islets. Optimized decellularization protocols resulted in hydrogels with distinctive viscoelastic properties that correlated to their matrix composition. The in situ 3-D encapsulation of human or rat islets within ECM hydrogels resulted in improved functional stability over standard culture conditions. Islet composition and morphology were also altered, with enhanced retention of islet-resident endothelial cells and the formation of cord-like structures or sprouts emerging from the islet spheroid. These supportive 3-D physiomimetic ECM hydrogels can be leveraged within microfluidic platforms for the long-term culture of islets.
Subject(s)
Cells, Immobilized/cytology , Extracellular Matrix/chemistry , Hydrogels/chemistry , Islets of Langerhans/cytology , Tissue Scaffolds/chemistry , Animals , Cells, Cultured , Cells, Immobilized/transplantation , Elasticity , Extracellular Matrix/transplantation , Extracellular Matrix/ultrastructure , Humans , Islets of Langerhans Transplantation , Male , Rats , Rats, Inbred Lew , Swine , ViscosityABSTRACT
Cell-based therapies for the treatment of diabetes, generally aim to provide long-term glucose regulated-insulin delivery using insulin producing cells. The delivery platform is crucial for the therapeutic outcome as well as for immunoisolation of the entrapped cells. We have developed a novel artificial pancreas encapsulation platform for the treatment of diabetes that is based on solubilized whole porcine pancreatic extracellular matrix (ECM). These unique capsules were used to entrap human liver cells and mesenchymal stem cells that were induced to differentiate into glucose-regulated insulin-producing cells. We demonstrate that the ECM-microcapsule platform provides a natural fibrous 3D niche, supporting cell viability and differentiation, while significantly improving insulin delivery. In vivo, ECM-encapsulated cells were shown to be non-immunogenic, and most importantly, to significantly improve the glycemic control in diabetic mouse preclinical model, thus establishing a proof-of-concept for this new cell-based insulin delivery platform.