The Sympathetic Nervous System and the Kidney: its Importance in Renal Diseases

Abstract

There is a two-way relation between the sympathetic nerve system and the kidney. On the one hand the sympathetic nerve system affects renal function, i.e. renal hemodynamics, renin secretion and tubular sodium transport. On the other hand the kidney is the source of activating afferent signals, presumably via stimulation of chemoreceptors and baroreceptors. This concept is supported by clinical observations in endstage and pre-endstage renal disease, where sympathetic overactivity is present. It has been shown to depend on the presence of the diseased kidney and is abolished by bilateral nephrectomy. Experimentally, interruption of afferent nerve traffic by dorsal rhizotomy partially prevents hypertension in renal damage models. Imidazoline-preferring binding sites are found in the kidney. In the rat, natriuresis is elicited by injection of moxonidine into the renal artery. In humans, there is no definite evidence for a natriuretic effect, but some observations point in this direction. In renal disease, the issue arises whether sympathetic overactivity contributes to progression of renal failure. Indirect evidence in this direction could be the marked acceleration of progression by smoking, a state of known sympathetic overactivity. In experimental models of renal damage, treatment with moxonidine in antihypertensive doses markedly attenuated development of glomerulosclerosis. Preliminary observations show that even non-antihypertensive doses of moxonidine interfere with the development of glomerulosclerosis. Sympathicolytic agents are obviously rational in the antihypertensive therapy of the renal patient, because uraemia is a state of sympathetic overactivity and because blood pressure-independent effects of sympathetic activation on progression are likely.