Unifying hypothesis of sodium and water regulation in health and disease.

Sodium and water retention is characteristic of edematous disorders including cardiac failure, cirrhosis, nephrotic syndrome, and pregnancy. Nonosmotic vasopressin release has been implicated in the water retention of these edematous disorders. The nonosmotic release of vasopressin is consistently associated with activation of the sympathetic nervous and renin-angiotensin-aldosterone systems in both experimental animals and in edematous patients. Moreover, the sympathetic nervous system has been shown to be involved in the nonosmotic release of vasopressin and activation of the renin-angiotensin system. These findings have led to our proposal that body fluid volume regulation involves the dynamic interaction between cardiac output and peripheral arterial resistance. Neither total extracellular fluid volume nor blood volume is a determinant of renal sodium and water excretion. Rather, renal sodium and water retention is initiated by a decrease in effective arterial blood volume (EABV) due to either a fall in cardiac output or peripheral arterial vasodilation. The acute response to a decrease in EABV involves vasoconstriction mediated by angiotensin, sympathetic mediators, and vasopressin. The slower response to restoring EABV involves vasopressin-mediated water retention and aldosterone-mediated sodium retention. The resultant renal vasoconstriction limits the distal tubular delivery of sodium and water, thus maximizing the water-retaining effect of vasopressin and impairing the normal escape from the sodium-retaining effects of aldosterone. The elevated glomerular filtration rate and filtered sodium load in pregnancy allows increased distal sodium and water delivery in spite of a decrease in EABV, thus limiting edema formation during gestation.