R. T. Kunau

Clarification of the site of action of chlorothiazide in the rat nephron.

The saluretic effect of the thiazide diuretics has been attributed to inhibition of sodium reabsorption in the distal nephron of the kidney. Recent micropuncture studies have shown, however, that chlorothiazide administration can also inhibit sodium reabsorption in the proximal convolution. To clarify the site of the saluretic effect of chlorothiazide, these micropuncture studies examined the effect of chlorothiazide on chloride transport in the nephron. The effect of chlorothiazide on chloride transport was studied because chlorothiazides effectiveness as a saluretic is largely due to its ability to enhance sodium chloride excretion; if only changes in sodium transport are examined, it would be then difficult to determine if sodium as bicarbonate or as chloride is affected, since chlorothiazide can inhibit carbonic anhydrase. One group of rats was studied before and after 15 mg/kg per h chlorothiazide. For comparison, another group of rats was studied before and after 2 mg/kg per h benzolamide, a carbonic anhydrase inhibitor. Fractional chloride delivery from the proximal tubule was similarly increased in both groups from 59.4 to 71.0% by chlorothiazide administration, Pless than 0.0001, and from 54.3 to 68.2% by benzolamide administration, P less than 0.001. The increased delivery very of chloride from the proximal tubule was largely reabsorbed before the early distal tubule as fractional chloride delivery to this site increased only from 5.08 to 7.40% after chlorothiazide administration, P less than 0.001, and from 4.50 to 6.29% after benzolamide administration, P less than 0.01. Benzolamide had no effect on chloride reabsorption in the distal convoluted tubule. However, chlorothiazide administration resulted in a marked decrease in distal tubular chloride reabsorption, the fraction of filtered chloride present at the late distal tubule incresing from 1.24 to 6.25%, P less than 0.001. Fractional chloride excretion in the urine increased from 0.29 to 3.44%, P less than 0.001, after chlorothiazide, but did not change after benzolamide. The influence of chlorothiazide on proximal chloride transport presumably is related to its ability to inhibit renal carbonic anhydrase. However, it is not the effect of chlorothiazide in the proximal convolution but rather its effect in the distal convoluted tubule which is primarily responsible for its ability to be an effective saliuretic.

Studies on the Mechanism of Reduced Urinary Osmolality after Exposure of the Renal Papilla

Studies were performed in Munich-Wistar rats to determine whether changes in papillary plasma flow might be responsible for the concentrating defect which occurs after exposure of the extrarenal papilla. Papillary plasma flow was measured by (125)I-albumin accumulation. Initial studies in hydropenic animals revealed that papillary plasma flow was 40% higher in the kidney with the exposured papilla, 41 vs. 29 ml/min per 100 g of papilla (P < 0.001). This increase in papillary plasma flow was detectable 15 or 45 min after removing the ureter. Because it was unclear whether the rise in papillary plasma flow was a cause or the result of the fall in urine osmolality, similar studies were performed in animals undergoing a water diuresis. In this setting, papillary plasma flow still increased on the exposed side compared to the control side, 81 vs. 60 ml/min per 100 g, despite similarly low urine osmolalities of 155 and 174 mosmol/kg, respectively. This finding is compatible with the possibility that papillary exposure per se causes an increase in papillary plasma flow and that this hemodynamic alteration may lead to a reduction in urinary osmolality secondary to washout of the medullary interstitium. A final group of hydropenic rats was given either indomethacin or meclofenamate before removing the ureter. In these studies, there was no difference in either the papillary plasma flow or the urine osmolality between control and exposed kidneys. It is therefore suggested that opening the ureter induces an increase in papillary plasma flow by some mechanism which may involve an alteration in prostaglandin synthesis.

Direct measurement of papillary collecting duct sodium transport in the rat. Evidence for heterogeneity of nephron function during Ringer loading.

It has been suggested that collecting duct sodium transport was inhibited by extracellular volume expansion. To directly evaluate this possibility, micropuncture of the papillary collecting duct of young rats was performed during hydropenia and Ringer loading. The possibility of heterogeneity of nephron function was evaluated during Ringer and hyperoncotic albumin loading by comparing the delivery of sodium to the end of the distal tubule of superficial nephrons with papillary base delivery. During hydropenia (n = 14), sodium delivery to the base averaged 0.95% of the filtered sodium load and reabsorption along the collecting duct was noted from base to tip in each collection pair averaging 0.80% of the filtered load. During Ringer loading, sodium delivery to the base was markedly greater than in hydropenia, 11.8 vs. 0.95% of the filtered load (P less than 0.001). Yet, sodium reabsorption was also much greater, 6 vs. 0.8% (P less than 0.001). In 13 paired collections, during Ringer loading, sodium delivery to the papillary base, 12.2% of the filtered load, was consistently greater than late distal tubular delivery from superficial nephrons. 8% (P less than 0.005). In contrast, reabsorption of sodium from late distal tubule to papillary base was found during albumin infusion, 6.2 vs. 3.1% (P less than 0.001). Therefore, these studies demonstrate that: (a) the delivery of sodium to and reabsorption along the papillary collecting duct were markedly greater during Ringer loading than in hydropenia; (b) the amount of sodium delivered to the papillary base was greater than the delivery to the end of the distal tubule of superficial nephrons during Ringer loading, suggesting that deeper nephrons deliver more sodium to the collecting duct in this setting; and (c) the difference in sodium excretion between Ringer loading and hyperoncotic albumin infusion is due to events occurring between the late distal tubule of superficial nephrons and the base of the papillary collecting duct.

The effect of an acute increase in renal perfusion pressure on sodium transport in the rat kidney.

We used micropuncture techniques to examine the infrarenal response to an acute elevation of the renal perfusion pressure. In one series of studies (epinephrine, group I) the renal perfusion pressure was acutely increased by intravenous epinephrine infusion; in another series, by bilateral carotid occlusion and vagotomy. A third series of studies I epinephrine, group II) was performed identically to the epinephrine, group I, studies except that the renal perfusion pressure was held constant during the epinephrine infusion by suprarenal aortic constriction. After epinephrine infusion (group I) and following bilateral carotid occlusion and vagotomy the renal perfusion pressure increased, from 119 ± 1.0 (sem) to 166 ± 1.85 mm Hg and from 122 ± 5.9 to 168 ± 3.1 mm Hg, respectively. Fractional sodium excretion rose from 2.31 ± 0.349b to 5.09 ± 0.58% (P < 0.001) after epinephrine and from 1.80 ± 0.71 to 6.40 ± 1.0% (P < 0.001) following carotid occlusion and vagotomy. In neither study, however, did we find that the increase in renal perfusion pressure changed the glomerular filtration rate (CFR) (both kidneys) or fractional sodium delivery from the superficial cortical late distal tubule. Furthermore, we found that epinephrine infusion at a constant renal perfusion pressure (epinephrine, group II) did not affect fractional sodium excretion, although a small, but significant, decrease in the CFR and sodium delivery from the superficial late distal tubule occurred. These data suggest that the natriuresis which follows an acute elevation of the renal perfusion pressure cannot be attributed to enhanced sodium delivery from superficial nephrons but must result from (1) inhibition of sodium reabsorption in inner cortical nephrons or (2) an effect on sodium transport in the collecting system.

Effect of acute hypercapnia on renal and proximal tubular total carbon dioxide reabsorption in the acetazolamide-treated rat

The present study evaluates the effect of acute hypercapnia on renal total CO2 (tCO2) reabsorption after inhibition of renal carbonic anhydrase. Simultaneous renal clearance studies and free-flow micropuncture studies of the superficial proximal tubule were performed on plasma-repleted Sprague-Dawley rats treated with acetazolamide, 50 mg/kg body weight. Acute hypercapnia (arterial PCO2, 120 mmHg; blood pH, 7.02) was induced by ventilation with a 10% CO2-90% O2 gas mixture. Control rats (PCO2, 49.5 mmHg, pH 7.34) were ventilated with room air. The renal fractional excretion of tCO2 was approximately 20% lower in the hypercapnic group compared with the rats given acetazolamide alone. Acute hypercapnia reduced the fractional delivery of tCO2 to the late proximal tubule by a comparable amount. The absolute proximal reabsorption of tCO2 was increased by hypercapnia to 410 +/- 47 vs. 170 +/- 74 pmol X min-1, P less than 0.05. The single nephron glomerular filtration rate was 32.6 +/- 0.7 nl X min-1 in the hypercapnic group and 43.8 +/- 1.7 nl X min-1 in the rats given acetazolamide only, P less than 0.01. Acute hypercapnia enhances renal sympathetic nerve activity. To eliminate this effect, additional experiments were performed in which the experimental kidney was denervated before study. Denervation prevented the change in the single nephron filtration rate during acute hypercapnia, but absolute and fractional proximal tCO2 reabsorption remained elevated in comparison to denervated controls. The concentration of H2CO3 in the late proximal tubule, calculated from the measured luminal pH and bicarbonate concentration and the estimated cortical PCO2, was higher in the hypercapnic group, which was a finding compatible with H2CO3 cycling from lumen into proximal tubular cell, which provided a source of hydrogen ions for secretion.