SODIUM MOVEMENT ACROSS SINGLE PERFUSED PROXIMAL TUBULES OF RAT KIDNEYS

Overview

Journal J Gen Physiol

Specialty Physiology

Date 1964 Jul 1

PMID 14192552

Citations 41

Authors

G Giebisch

R M KLOSE

G Malnic

W J Sullivan

E E WINDHAGER

Affiliations

Soon will be listed here.

Abstract

Using perfusion techniques in single proximal tubule segments of rat kidney, the relationship between net sodium movement and active transport of ions, as measured by the short-circuit method, has been studied. In addition, the role of the colloid-osmotic pressure gradient in proximal transtubular fluid and sodium movement has been considered. Furthermore, the limiting concentration gradient against which sodium movement can occur and the relationship between intratubular sodium concentration and fluid transfer have been investigated. Comparison of the short-circuit current with the reabsorptive movement of sodium ions indicates that this process is largely, perhaps exclusively, active in nature. No measurable contribution of the normally existing colloid-osmotic pressure gradient to transtubular water movement was detected. On the other hand, fluid movement across the proximal tubular epithelium is dependent upon the transtubular sodium gradient and is abolished when a mean concentration difference of 50 mEq/liter is exceeded.

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