Regional Blood Flow Dynamics in Response to Insulin and IGF-1 in Diabetic Animals

Abstract

Vascular changes in diabetes characterized by increased contractile or decreased dilator responses have been demonstrated in isolated blood vessels as well as in vivosystems. Previous studies in our laboratory have demonstrated that insulin and insulin like growth factor-1 (IGF-1) can decrease mean arterial pressure (MAP) and increase blood flow in vascular beds. In this study we evaluated the regional hemodynamic responses to insulin and IGF-1 in normal and diabetic rats. Normal male rats were made diabetic with streptozotocin (55 mg/kg) i.v. and maintained 60 to 70 days. On the day of the study the rats were anesthetized with urethane/chloralose, the femoral artery and vein cannulated for blood pressure monitoring and blood sampling or infusion, respectively. Pulsed-Doppler flow probes were placed around the iliac artery, renal artery and superior mesenteric artery to monitor blood flow. Insulin (16 nmol/kg) was infused as a bolus via the femoral vein and it decreased the MAP approximately 17% in both normal and diabetic rats. Insulin enhanced vascular flow (expressed as conductance) in the iliac and renal vascular bed but not the superior mesenteric vascular bed in normals. In diabetic rats the flow response to insulin compared to normals was attenuated in the iliac and renal vascular beds and increased in the superior mesenteric vascular bed. A bolus infusion of IGF-1 (16 nmol/kg) also decreased the MAP in normals and diabetics. IGF-1 increased vascular flow in all three vascular beds in normals but in the diabetics the response to IGF-1 was artenuated in the iiiac, increased in h e renal vascular bed and suppressed in the superior mesenteric vascularure. From these studies we conciude that diabetes is associated with an anenllared vascular response to insulin and IGF-1 in the iliac and renal vessels while insulin augments and IGF-1 decreases blood flow in the superior mesenteric vasculature