Human skeletal muscle feed arteries: evidence of regulatory potential

Abstract

Recently, it has been recognized that human skeletal muscle feed arteries can be harvested during exploratory surgery for melanoma. This approach provides vessels for in vitro study from a wide spectrum of relatively healthy humans. Although, the regulatory role of skeletal muscle feed arteries in rodent models has been documented, whether such vessels in humans possess this functionality is unknown. Therefore, skeletal muscle feed arteries (~950μm OD) from 10 humans (48±4, 27-64years) were studied using pressure myography. Vessel function was assessed using potassium chloride (KCl), phenylephrine (PE), acetylcholine (ACh) and sodium nitroprusside (SNP) concentration-response curves (CRCs) to characterize non-receptor and receptor-mediated vasoconstriction as well as endothelium-dependent and independent vasodilation respectively. To understand the physiological relevance of the diameter changes as a result of pharmacological stimulation, the estimated conductance ratio (CR) was calculated. Vessel function protocols revealed significant vasoconstriction in response to PE and KCl (35±6; 43±9%vasoconstriction, respectively) and significant vasodilation with ACh and SNP (85±7; 121±17% vasodilation, respectively). Both PE and KCl significantly reduced the CR (0.26±0.05 and 0.23±0.07, respectively), whereas ACh and SNP increased the CR (2.56±0.10 and 5.32±1.3, respectively). These novel findings provide evidence that human skeletal muscle feed arteries are capable of generating significant diameter changes that would translate into significant changes in vascular conductance. Thus, human skeletal muscle feed arteries likely play a significant role in regulating vascular conductance and subsequently blood flow in vivo.