Central and peripheral mechanisms of arterial pressure lability following baroreceptor denervation

Abstract

Deafferentation of sinoaortic baroreceptors produces a marked increase in the lability of arterial pressure that is sustained chronically. Studies reviewed in this paper were designed to determine the mechanisms responsible for generating arterial pressure lability. Pharmacological interruption of the humoral vasopressin and angiotensin systems failed to alter arterial pressure lability. In contrast, blockade of sympathetic nervous system transmission at both ganglionic and alpha-adrenergic receptor levels significantly attenuated lability. A similar effect was observed with the peripheral neurotoxin, 6-hydroxydopamine. After blockade of sympathetic transmission, a further reduction in lability was produced by blocking the renin-angiotensin or vasopressin systems. The dissociation of the level of arterial pressure from lability was achieved with parachloroamphetamine which raised arterial pressure but reduced lability. A substantial peripheral contribution to lability was obtained in experiments in which the alpha-adrenergic agonist, phenylephrine, produced a marked increase in lability in both normal and baroreceptor-denervated animals in which humoral and neural transmission were blocked. These data demonstrate that following baroreceptor deafferentation, arterial pressure lability is produced primarily by the sympathetic nervous system and secondarily by circulating humoral factors that appear to act on vascular smooth muscle to induce fluctuations in the level of arterial pressure.