The impact of hyperglycemia and the presence of encapsulated islets on oxygenation within a bioartificial pancreas in the presence of mesenchymal stem cells in a diabetic Wistar rat model

Veriter, Sophie [UCL] Aouassar, Najima [UCL] Adnet, Pierre-Yves [UCL] Paridaens, Marie-Sophie [UCL] Stuckman, Charlotte Jordan, Bénédicte [UCL] Karroum, Oussama [UCL] Gallez, Bernard [UCL] Gianello, Pierre [UCL] Dufrane, Denis [UCL]

This study investigates the potential of bone marrow (BM-MSCs) versus adipose mesenchymal stem cells (AMSCs) to potentiate the oxygenation of encapsulated islets in a subcutaneous bioartificial pancreas. Oxygen pressures (inside subcutaneous implants) were followed in vivo (by electronic paramagnetic resonance) in non-diabetic/diabetic rats transplanted with encapsulated porcine islets or empty implants up to 4 weeks post-transplantation. After graft explantation, neoangiogenesis surrounding the implants was assessed by histomorphometry. Angiogenic properties of BM-MSCs and AMSCs were first assessed in vitro by incubation of the cells in hypoxia chambers, under normoxic/hypoxic and hypo-/hyperglycemic conditions, followed by quantification of vascular endothelial growth factor (VEGF) release. Second, the in vivo aspect was studied by subcutaneous transplantation of encapsulated BM-MSCs and AMSCs in diabetic rats and assessment of the cells' angiogenic properties as described above. Diabetic state and islet encapsulation induced a significant decrease of oxygenation of the subcutaneous implant and an increased number of cells expressing VEGF. AMSCs demonstrated a significantly higher VEGF secretion than BM-MSCs in vitro. In vivo, AMSCs improved the implant's oxygenation and vascularization. Diabetes and islet encapsulation significantly reduced the oxygenation of a subcutaneous bioartificial pancreas. AMSCs can improve oxygenation by VEGF release in hypoxia and hyperglycemia states.