Determinants of deranged sodium and water homeostasis in decompensated cirrhosis.

Previous studies from this laboratory have demonstrated that the redistribution of blood volume and concomitant central hypervolemia induced by water immersion to the neck (NI) results in a significant natriuresis, kaliuresis, and diuresis. The NI model was utilized to assess the role of "effective volume" and hyperaldosteronism in the impairment of sodium and water handling in cirrhosis. Eleven cirrhotic patients were studied twice while in balance on a 10 mEq. Na, 100 mEq. K diet: control and NI. The conditions of seated posture and time of day were identical. UNaV was constant throughout C, ranging from 1 to 2 muEq per minute. During NI, UNaV increased progressively from 1 +/- 1 (S.E.M.) during the prestudy hour to 89 +/- 32 muEq per minute during hour 5 of NI (p less than 0.02), greatly exceeding the comparable value found in normal subjects on an identical diet. (See article).

Failure of water immersion to influence parathyroid hormone secretion and renal phosphate handling in normal man.

Previous studies from this laboratory have demonstrated that the redistribution of blood volume and concomitant relative central hypervolemia induced by water immersion to the neck (NI) results in a significant natriuresis which is quantitatively identical to that induced by the acute administration of 2 L. of saline. Since the central hypervolemia induced by NI occurs without concomitant alterations in serum ionized calcium concentration (Ca++), the NI model was utilized to assess the role of volume in the regulation of PTH secretion in man. Seven normal subjects were studied following 11 hours of dehydration on two occasions, control and NI. The conditions of seated posture and time of day were identical. Blood for ionized calcium and PTH was obtained at 30-minute intervals for 6 hours. NI resulted in a significant increase in UNaV from a prestudy value of 78 +/- 12 (S.E.M.) to 222 +/- 20 muEq per minute (p less than 0.001). Concomitantly, Ca++ remained constant, ranging between 4.57 to 4.71 mg. per cent. Despite the volume-induced natriuresis, PTH was not altered throughout 5 hours of NI, ranging from 36 +/- 7 to 45 +/- 5 mul-Eq. per milliliter. Phosphate excretion remained constant. These data indicate that central volume expansion does not alter PTH in normal man when the variables of ionized calcium, posture, and time of day are controlled. Furthermore, the current demonstration of the absence of phosphaturia during immersion despite the probability that the distal delivery of phosphate was enhanced, permits consideration of the possibility that the concept of a distal tubular reabsorptive site for phosphate may be applicable to man.

Suppression of plasma renin and plasma aldosterone during water immersion in normal man.

Previous studies from this laboratory have demonstrated that the redistribution of blood volume and concomitant relative central hypervolemia induced by water immersion to the neck (NI) results in a significant natriuresis which is quantitative identical to that induced by the acute administration of 2 liters of saline. Since the central hypervolemia induced by NI occurs without concomitant alterations in serum sodium and potassium concentration, the NI model was utilized to assess the role of volume in the regulation of both plasma renin (PRA) and plasma aldosterone (PA) in man. Nine normal subjects were studied on two occasions while in balance on a 10 meq Na, 100 meq K diet; Control and NI. The conditions of seated posture and time of day were identical. Blood for PRA and PA was obtained at 30-min intervals for 6 h. NI produced a profound suppression of PRA as early as 30 min with maximal suppression (62%) by 180 min (P less than 0.001). Recovery from NI was associated with a prompt return to pre-study levels. The changes in PA paralleled those of PRA with regard to both the rapidity and magnitude of the suppression (r = 0.993: P less than 0.001). These data emphasize the importance of central volume per se as a primary determinant of PRA and PA regulation in normal man. Furthermore, the current studies confirm the importance of the renin-angiotensin axis in the control of volume-related changes in PA in normal man. The ability of NI to induce a prompt and parallel suppression of PRA and PA without concomitant alterations in plasma composition, suggests that NI may be a preferred investigative tool for assessing the effects of volume expansion on renin-aldosterone.

Comparison of water immersion and saline infusion as a means of inducing volume expansion in man.

Although previous studies have demonstrated that water immersion to the neck (NI) results in both central hypervolemia and a significant natriuresis, it is unclear whether the magnitude of the "volume stimulus" of NI is comparable to that induced by the extracellular fluid volume expansion (ECVE) induced by acute saline administration. The present study was undertaken therefore to compare the natriuresis induced by these two different stimuli. All subjects were studied on four occasions while in balance on a diet containing 150 meq of sodium and 80 meq of potassium daily: seated control; seated immersion; and saline administration in both the seated and recumbent posture. The increment in UNaV during NI was indistinguishable from that of seated saline. Similarly, the kaliuretic response during NI was similar to that induced by seated saline infusion. In contrast, supine saline infusion resulted in a greater increment in UNaV than either NI or seated saline. The present data indicate that the "volume stimulus" of immersion is identical with that of standard saline-induced ECVE in normal seated subjects. Furthermore, the ability of NI to induce a natriuresis without a concomitant increase in total blood volume and with a decrease in body weight, rather than the increase which attends saline infusion, suggests that NI may be a preferred investigative tool for assessing the effects of ECVE in man.

Suppression of ADH during water immersion in normal man.

Since previous studies from this laboratory have demonstrated that the redistribution of blood volume and concomitant relative central hypervolemia induced by water immersion to the neck causes a profound natriuresis and a suppression of the renin-aldosterone system, it was of interest to assess whether the diuresis induced by immersion was mediated by an analogous inhibition of ADH. The effects of water immersion on renal water handling and urinary ADH excretion were assessed in 10 normal male subjects studied following 14 h of overnight dehydration on two occasions, control and immersion. The conditions of seated posture and time of day were identical. During control ADH persisted at or above prestudy values. Immersion resulted in a progressive decrease in ADH excretion from 80.1 plus or minus 7 (SEM) to 37.3 plus or minus 6.3 muU/min (P smaller than 0.025). Cessation of immersion was associated with a marked increase in ADH from 37.3 +/- 6.3 muU/min to 176.6 +/- 72.6 muU/min during the recovery hour (P smaller than 0.05). Concomitant with these changes urine osmolality decreased significantly beginning as early as the initial hour of immersion from 1044 +/- 36 to 542 +/- 66 mosmol/kg H2O during the final hour of immersion (P smaller than 0.001). Recovery was associated with a significant mean increase in Uosm of 190 +/- 40 mosmol/kg H2O over the final hour of immersion (P smaller than 0.001). The suppression of ADH occurred without concomitant changes in plasma tonicity. These studies are consistent with the suggestion that in hydrated subjects undergoing immersion suppression of ADH release contributes to the enhanced free water clearance, which has been previously documented.