Filtration rate and stop-flow pressure feedback responses to nephron perfusion in the dog

Abstract

Experiments were performed to evaluate the influence of the distal tubular feedback mechanism on glomerular function in the dog. Single nephron glomerular filtration rate (SNGFR) and stop-flow pressure (SFP) were measured from early segments of proximal tubules during alterations in distal perfusion rate (via a late proximal puncture site) and perfusate composition. Perfusion rate (PR) was varied from 16 to 68 nl/min with a microperfusion pump. The intermediate segment of the nephron was blocked with a solid wax cast, thus preventing retrograde influences of the microperfusion procedure. During perfusion with an ultrafiltrate of plasma and an artificial tubular fluid solution (ATF), SNGFR decreased from 63 +/- 2.6 (SE) nl/min at a PR of 16 nl/min to 20 +/- 2.4 nl/min at a PR of 63 +/- 2.6 nl/min. At a PR of 16 nl/min, SFP was 48 +/- 1.3 mmHg with ultrafiltrate and ATF. Increases in PR to 68 nl/min led to a reduction in SFP to 26 +/- 1.5 mmHg. SFP was also measured during changes in PR with various electrolyte solutions of decreasing complexity. Elimination or substitution of Na+, K+, Cl-, HCO3-, and Ca2+ did not significantly alter the magnitude of the feedback response to increases in PR to 68 nl/min. These results confirm the existence of a feedback system in the dog capable of adjusting glomerular function in response to changes in distal perfusion rate. The results based on the various perfusion solutions fail to indicate a unique requirement for any specific component.