Blood Flow Regulation and Inflammatory Response in Experimental Models of Diabetes

Type 2 diabetes is caused by defect pancreatic islet β-cells together with peripheral insulin resistance. The disease is often accompanied by obesity with associated low-grade visceral adipose tissue inflammation, which contributes to insulin resistance. As a consequence of, and a possible compensation for the increased insulin demand, blood flow to the pancreatic islets is increased in animal models of diabetes. This increased blood perfusion might with time affect the vascular network as well as β-cells within the islets. This thesis investigates the role of changes of blood perfusion in pancreatic islets and adipose tissues, as well as the recruitment to and composition of leukocyte subpopulations in insulin-sensitive tissues in experimental models of diabetes. Blood flow measurements in islets and adipose tissues of rats and mice were performed using the microsphere technique, while leukocyte recruitment was studied in the mouse cremaster muscle using intravital microscopy. Increased islet blood flow was observed in the GK rat model of type 2 diabetes, which was decreased by acute as well as continuous 2-week inhibition of β3-adrenoceptors without affecting plasma insulin concentrations. Increased inflammatory leukocyte recruitment was observed in both alloxan-induced and high-fat diet-induced diabetes. However, an impaired bacterial clearance was observed in diabetic mice, which was due to impaired phagocytosis. A gender difference was detected in mice fed a high-fat diet, since obese female mice did not show increased levels of pro-inflammatory circulatory markers or inflammatory leukocytes in the adipose tissue. The main effector cell in the adipose tissue inflammation in high-fat-fed male mice seemed to be the pro-inflammatory macrophage. The Treg population in adipose tissue was increased in female mice, but remained unchanged in male mice on high-fat diet. In conclusion, increased islet blood flow in type 2 diabetes could be reversed by β3-adrenoceptor inhibition, which may maintain islet function. The diabetes-associated hyperglycemia activated leukocytes but impaired their phagocytic ability. High-fat-fed female mice showed less peripheral inflammation due to a smaller number of recruited inflammatory macrophages and a high-fat diet-induced Treg population in intra-abdominal adipose tissues