Nitric oxide and the regulation of large artery stiffness: from physiology to pharmacology.

Abstract

The association between arterial stiffening and aging is well described and can be observed in almost all populations worldwide. A number of other cardiovascular risk factors including diabetes and cigarette smoking are also associated with increased large artery stiffness, often referred to as “premature arterial stiffening.” It is now apparent that the aortic pulse wave velocity (PWV), a measure of arterial distensibility, predicts outcome in a variety of different populations, including hypertensives,1 diabetics,2 individuals with end-stage renal disease (ESRD),3 and even in older adults.4 Indeed, in some populations, aortic PWV is a better predictor of future events than peripheral blood pressure.4 Moreover, arterial stiffening may be more than just a marker of cardiovascular risk; stiffening may also play a more direct role in the development of atherosclerotic plaques. Thus, arterial stiffness would appear to be a novel therapeutic target for the prevention of excess cardiovascular morbidity and mortality. To exploit such an exciting prospect fully, it is necessary to understand the factors regulating arterial stiffness. Traditionally, the stiffness of a vessel was viewed as simply a function of the structural elements of the vessel wall and distending (mean arterial) pressure. However, the large arteries also have a generous coat of smooth muscle, which can alter the distribution of stresses between the elastic and collagenous fibers of the vessel wall and thus alter arterial stiffness. Because smooth muscle tone is influenced by a number of circulating and local vasoactive mediators, arterial stiffness may be actively regulated, and indeed modifiable, at least in the short-term. The muscular arteries have a rich sympathetic innervation, and catecholamines are known to alter smooth muscle tone. Moreover, removal of the vascular endothelium in animals alters large artery stiffness,5,6 suggesting that endothelial-derived substances regulate arterial stiffness in vivo. However, the endothelium …