The relative contributions of reabsorptive rate and redistributed nephron filtration rate to changes in proximal tubular fractional reabsorption during acute saline infusion and aortic constriction in the rat

The absolute rate of reabsorption by superficial rat proximal tubules was measured by the in situ microperfusion technique under conditions of hydropenia, infusion of saline, and infusion of saline plus aortic constriction sufficient to decrease whole kidney filtration rate below hydropenic levels. Fractional reabsorption was measured in adjacent filtering nephrons by collecting and recollecting tubular fluid from late proximal convolutions during each experimental condition. During hydropenia, the absolute rate of proximal tubular reabsorption averaged 3.56 +/-0.60 nl/min per mm and late proximal tubular fractional reabsorption averaged 0.56 +/-0.10. From these two measurements and measurements of tubule length to the site of micropuncture, a value for filtration rate was calculated for filtering nephrons. During hydropenia this value averaged 32.9 +/-7.1 nl/min. Saline infusion increased sodium excretion to 5.5% of the filtered load as the absolute rate of proximal tubular reabsorption decreased 38% and fractional reabsorption decreased 45%. Calculated superficial nephron filtration rate increased 21% which on the average was identical with the simultaneously measured increase in whole kidney filtration rate. Similar results were obtained in a separate group of animals by the technique of total collection of late proximal tubular fluid. Aortic constriction during saline infusion decreased whole kidney and calculated nephron filtration rate to the same degree and to values lower than those during hydropenia. Fractional reabsorption increased but not to hydropenic values. The persistent natriuresis during aortic constriction was associated with a continued depression of the absolute rate of proximal tubular reabsorption which was sufficient to maintain an increased delivery of filtrate out of the proximal tubule despite the fall in nephron filtration rate. These results indicate that depressed fractional reabsorption in the proximal tubule during acute saline infusion is due predominantly to a decrease in absolute reabsorptive rate and to a lesser extent to an increase in superficial nephron filtration rate which is proportional to the increase in whole kidney filtration. Continued natriuresis when filtration rate is decreased during saline infusion can be accounted for entirely by the persistent large reduction in the absolute rate of proximal tubular reabsorption.     

The effect of bradykinin on proximal tubular sodium reabsorption in the dog: evidence for functional nephron heterogeneity

In a previous study we have found that acetylcholine, a renal vasodilator, inhibits fractional and absolute reabsorption of sodium in the proximal tubule of the dog. To delineate whether this effect on proximal tubular sodium reabsorption was related to alterations in renal hemodynamics or to a direct tubular action of the drug, free-flow micropuncture studies were performed in the dog in which the tubular fluid to plasma inulin ratio and nephron filtration rate were determined before and during the administration of a structurally different renal vasodilator, bradykinin. This agent increased sodium excretion from 12 to 96 muEq/min and decreased total kidney filtration fraction from 0.35 to 0.25. However, sodium reabsorption in the proximal tubule of the superficial nephrons was unchanged during bradykinin administration.Since it has been shown that a decrease in filtration fraction and presumably peritubular capillary protein concentration will decrease proximal tubular sodium reabsorption, studies were performed to determine whether the fall in total kidney filtration fraction seen with both vasodilators is paralleled by a similar change in the circulation of superficial nephrons. The results of these studies indicate that neither agent altered superficial nephron capillary protein concentration, hematocrit, or filtration fraction.In contrast, a decrease in capillary protein concentration, hematocrit, and filtration fraction was consistently demonstrated during the intrarenal infusion of 7.5-15 ml/min of Ringer's solution while an increase in these parameters occurred during the i.v. administration of norepinephrine, 60 mug/min. In the Ringer's infusion studies, both fractional and absolute sodium reabsorption in the proximal tubule were decreased concomitant with the fall in capillary protein concentration and hematocrit.THIS DATA SUGGESTS THAT: (a) the hemodynamic effect of renal vasodilatation is not the same in the circulation of all nephrons; (b) the inhibitory effect of acetylcholine on proximal tubular sodium reabsorption is due to a direct tubular action; (c) a decrease in capillary protein concentration and/or hematocrit does decrease proximal tubular sodium reabsorption; (d) although proximal reabsorption of sodium is unchanged in the superficial nephrons during bradykinin administration, a decrease in reabsorption may be present in deeper nephrons in which filtration fraction is decreased.     

Renal handling of sodium and water in the hypothyroid rat: Clearance and micropuncture studies

Hypothyroid rats were examined with conventional renal clearance and micropuncture techniques to elicit the mechanism and site within the nephron responsible for the increased salt and water excretion observed in these animals. When compared with age-matched control rats, a decrease in inulin clearance of 30% (P < 0.001) and in Hippuran clearance of 32% (P < 0.005) was observed in the hypothyroid rats. Absolute excretion of sodium and water was increased 3-fold (P < 0.02) and 2-fold (P < 0.025), respectively, while fractional excretion of sodium and water was increased 4.3-fold (P < 0.02) and 2.9-fold (P < 0.05), respectively, in the hypothyroid animals.Fractional proximal reabsorption of sodium as assessed from proximal tubular fluid to plasma ratios of inulin ([TF/P](IN)) was found to be decreased by 28% (P < 0.001) in the hypothyroid rats. Superficial single nephron filtration rate was reduced proportionately to the decrease in total filtration rate in the hypothyroid rats.These data indicate that the proximal tubule is one of the sites of diminished sodium and water reabsorption in the hypothyroid rat. The data also suggest that the observed decrease in glomerular filtration rate in the hypothyroid animals is not caused by a decrease in the number of functioning nephrons and that the observed increase in sodium and water excretion is not caused by a redistribution of filtrate from juxtamedullary to superficial nephrons. Although the exact mechanisms of the observed changes in proximal tubular function remain unknown, the data suggest that they are probably related to the lack of thyroid hormone. Whatever their mechanism, it appears that the enhanced sodium and water excretion observed in the hypothyroid animals must be determined by further reduction in tubular sodium reabsorption in the distal nephron.     

Renal tubular effects of chronic phosphate depletion.

The effects of chronic phosphate depletion on renal tubular function were evaluated by micropuncture and free water clearance studies in the dog. Proximal tubular punctures demonstrated that chronic hypophosphatemia led to a reduction in ratio of tubular fluid to plasma inulin in late superficial tubular from 1.59+/-0.08 in control animals to 1.29+/-0.06 in phosphate-depleted dogs, with proportional inhibition of calcium and sodium reabsorption. The chronic decrease in proximal tubular fluid reabsorption was confirmed by the analysis of sustained water diuresis in conscious, phosphate-depleted dogs, before and after repletion of body PO4 stores, and in control animals. Urine flow rate/100 ml glomerular filtration rate (V/GFR) was significantly higher in PO4 DEPLETION THAN CONTROL (15.8+/-1.1 VS. 10.7+/-0.82). In addition, acetazolamide infusion did not increase V/GFR in phosphate-depleted dogs (15.8+/-1.1 vs. 17.16+/-0.9), supporting the conclusion that inhibition of proximal tubular fluid reabsorption was responsible for the elevated urine flow rate. PO4 repletion over 5 days reduced V/GFR to 9.2+/-0.7 despite no change in urine osmolality and no change in GFR, further suggesting a specific reversible alteration in proximal tubular reabsorption in phosphate depletion. Although hypercalciuria was a constant finding in phosphate depletion (fractional excretion of calcium of 2.04+/-0.4% vs. 0.47+/-0.13% in controls), the enhanced distal delivery of calcium was not a crucial factor; acute phosphate infusion reduced urinary calcium excretion to control values without affecting the reduced proximal tubular reabsorption in either intact or thyroparathyroidectomized phosphate-depleted dogs the change in distal nephron calcium reabsorption was independent of parathyroid hormone (PTH) levels since infusion of PTH failed to alter urinary calcium excretion. We conclude that chronic phosphate depletion leads to a reversible, sustained inhibition in proximal tubular reabsorptive fuction as well as a specific decrease in distal nephron calcium reabsorption. This latter reabsorptive defect is sensitive to phosplate infusion but not corrected by PTH.     

On the site of decreased fluid reabsorption after release of ureteral obstruction in the rat.

Fluid reabsorption in surface nephrons was studied by micropuncture 3 hours after release of complete left ureteral ligation (LUL) or after unilateral release of bilateral ureteral ligation (BUL). In 11 rats with LUL, glomerular filtration rate (GFR) averaged 0.23 +/- 0.04 ml. per minute in the experimental vs. 1.25 +/- 0.11 ml. per minute in the control kidney. GFR averaged 0.18 +/- 0.02 ml. per minute in BUL. Single nephron glomerular filtration rate (SNGFR) was decreased in the experimental kidney of LUL or BUL when determined at proximal or distal sites as compared to the SNGFR determined in shams or the left kidney following right ureteral ligation (RUL). Fractional water excretion was increased after release of obstruction. LUL 2.72 +/- 0.66 per cent; BUL 12.3 +/- 2.82 per cent when compared to sham-operated rats (0.48 +/- 0.07 per cent) or to the untouched kidneys of the RUL group (0.60 +/- 0.09 per cent). Despite increased water and sodium excretion after release of unilateral ureteral ligation and BUL there were marked differences in tubular fluid reabsorption between these two groups. Following release of LUL there was increased fractional water reabsorption along the accessible length of surface nephrons of the experimental kidney. At 55 per cent of proximal tubular length TF/Pin averaged 4.02 +/- 0.02 in LUL vs. 2.18 +/- 0.06 in shams. The mean TF/Pin at 90 per cent of distal tubular length was 31.0 +/- 1.37 in LUL vs. 10.6 +/- 0.08 in sham-operated rats. In contrast, water reabsorption after BUL was slightly but significantly suppressed proximally (TF/Pin 1.95 +/- 0.02) and markedly depressed distally (TF/Pin 3.35 +/- 0.29). These results suggest that the change in fluid reabsorption observed after relief of LUL is located at a site beyond the accessible length of surface nephrons, most likely in the collecting duct. However, the data could also be explained by alterations in fluid reabsorption in deep nephrons. The changes in fluid reabsorption seen following release of BUL reflect the additive effects of release of obstruction and a marked reduction in functioning nephron mass.     

Renal tubular site of action of felodipine

The renal tubular site of action of felodipine was localized using renal clearance and recollection micropuncture techniques in the anesthetized rat. In initial renal clearance experiments, felodipine (2.75 nM/kg/min i.v. X 60 min) had no effect on mean arterial pressure or glomerular filtration but significantly increased urinary flow rate, sodium and potassium excretion. In subsequent recollection micropuncture experiments, felodipine decreased mean arterial pressure but did not affect renal blood flow or renal vascular resistance or glomerular filtration rate; absolute and fractional urinary excretion of sodium and water, but not potassium, were increased. Proximal tubular and loop of Henle sodium, potassium and water reabsorption were not affected but distal tubular and collecting duct sodium and water (not potassium) reabsorption were decreased by felodipine. Felodipine is a vasodilator antihypertensive agent which, in doses which decrease mean arterial pressure in normotensive rats, increases urinary flow rate and sodium excretion by inhibiting distal tubular and collecting duct sodium and water reabsorption; potassium reabsorption or excretion is not affected. As a vasodilator antihypertensive agent, felodipine possesses beneficial natriuretic rather than detrimental sodium retaining properties.     

The Effects of Infusion of Water on Renal Hemodynamics and the Tubular Reabsorption of Sodium

Anesthetized dogs receiving an infusion of chlorothiazide and ethacrynic acid were given 600-ml infusions of distilled water or dilute dextrose solutions. The absolute rate of tubular sodium reabsorption was depressed, and the glomerular filtration rate was increased during the water loading, despite the associated decreases in plasma sodium concentration and decreases in the filtered load of sodium. The extent to which fractional sodium reabsorption decreased and the excretion of sodium increased was inversely related to the degree to which the filtered load of sodium was depressed as a result of the decreased plasma sodium concentration. We conclude that, in the presence of the diuretic blockade of distal tubular sodium reabsorption, infusion of water depresses proximal tubular reabsorption of sodium and that these changes are qualitatively similar to those previously observed during infusions of saline. Similar depression of tubular reabsorption of sodium and increased excretion of sodium occurred during water loading in the absence of diuretics in dogs undergoing saline diuresis, which presumably provided a high rate of distal sodium reabsorption before water loading.     

Effect of Medullary Tonicity on Urinary Sodium Excretion in the Rat

In previous reports from this laboratory we have suggested that a reduction in medullary tonicity decreases the thin ascending loop of Henle sodium reabsorption and is in part responsible for the magnitude for the natriuresis accompanying 10% body weight Ringer loading. According to this postulate, one would expect that the medullary washout associated with water diuresis would also result in a natriuresis, but this does not occur. It is possible, however, that increased delivery from the proximal tubule is necessary to demonstrate an effect of medullary tonicity on urinary sodium excretion. Micropuncture studies were designed to test that possibility by increasing distal delivery by 2% Ringer loading in animals with and without reduced medullary tonicity. In an initial series of experiments the α-adrenergic agonist clonidine was used to induce a water diuresis. When given alone, this agent caused a marked decrease in urine osmolality and an increase in urine flow rate but had no effect on proximal reabsorption in either superficial or juxtamedullary nephrons, and did not alter urinary sodium excretion. Volume expansion with 2% body weight Ringer solution resulted in a significant fall in proximal reabsorption and a trivial increment in sodium excretion. When this same degree of volume expansion was conferred on animals undergoing a water diuresis, a marked increase in absolute and fractional sodium excretion occurred. In a second group of studies medullary tonicity was reduced in the left kidney only by removal of the left ureter 1 h before micropuncture. When these animals were infused with 2% body weight Ringer solution, proximal reabsorption was decreased in juxtamedullary nephrons, and a marked increase in sodium excretion was observed only from the left kidney. Finally, the effect of water diuresis on fractional sodium delivery to the early and late distal tubule of superficial nephrons during 2% Ringer loading was evaluated. Delivery to both of these sites was comparable after 2% Ringer loading alone and during 2% Ringer loading plus water diuresis.     

Functional correlates of compensatory renal hypertrophy

The functional correlates of compensatory renal hypertrophy were studied by micropuncture techniques in rats after the removal of one kidney. The glomerular filtration rate increased to roughly the same extent in the whole kidney and in individual surface nephrons, resulting in a greater amount of sodium delivered to the tubules for reabsorption. The fraction of the glomerular filtrate absorbed [determined from the tubular fluid-to-plasma ratio (TF/P) for inulin] remained unchanged in both proximal and distal portions of the nephron. The way in which the tubules adjusted to nephrectomy, however, differed in proximal and distal convolutions. After nephrectomy, the reabsorptive half-time, indicated by the rate of shrinkage of a droplet of saline in a tubule blocked with oil, was unchanged in the proximal tubule but significantly shortened in the distal convoluted tubule. Nevertheless, steady-state concentrations of sodium in an isolated raffinose droplet in the distal as well as the proximal tubule were the same in hypertrophied kidneys as in control animals. Possible reasons for this paradox are discussed.Transit time through the proximal tubules was unchanged by compensatory hypertrophy, but transit time to the distal tubules was prolonged.Changes in renal structure resulting from compensatory hypertrophy were also found to differ in the proximal and the distal protions of the nephron. Although tubular volume increased in both protions, the volume increase was twice as great in the proximal tubule as in the distal. In order, therefore, for net reabsorption to increase in the distal tubule, where the changes in tubular volume are not so marked, an increase in reabsorptive capacity per unit length of tubule is required. This increase is reflected in the shortening of reabsorptive half-time in the oil-blocked distal tubule that was actually observed.     

The diuretic effect of calcium entry blockade in normals and hypertensive patients.

Calcium entry blockers have been shown to exert hemodynamic and diuretic effects in the kidney. The diuretic effects can be demonstrated most clearly in the isolated perfused kidney, not influenced by compensatory mechanisms such as a lower blood pressure or changes of hormones. However, they can also be shown in vivo in humans. We studied the renal effects of calcium entry blockade after the first dosage and after continued oral dosages of 20 mg nicardipine tid in patients with essential hypertension and in normotensive controls. Renal function was determined during maximal free water clearance, allowing estimation of changes in "proximal" and "distal" tubular sodium reabsorption. Results showed a natriuretic effect. In the control subjects, clearance results were compatible with a decrease of proximal and distal tubular reabsorption, but in the hypertensive group natriuresis was mainly achieved by an increase of the glomerular filtration rate and a decrease of fractional distal reabsorption. In both groups the natriuresis occurred concomitantly with a lower blood pressure. The ratio plasma renin activity/plasma aldosterone concentration increased, although nicardipine did not inhibit the increase of plasma aldosterone during angiotensin II infusion. Pre-treatment with the calcium entry blocker nitrendipine enhanced the natriuretic effect of atrial natriuretic factor (ANF) in sodium replete normal volunteers. Facilitation of sodium excretion by human ANF may be an additional diuretic mechanism of calcium entry blockers.     

The influence of extracellular volume expansion on renal phosphate reabsorption in the dog

Extracellular volume expansion (ECVE) was produced, by normal saline infusion, in five normal and six thyroparathyroidectomized anesthetized dogs while glomerular filtration rate was reduced by the inflation of an intra-aortic balloon located above the renal arteries. The effect of ECVE on the maximum renal tubular reabsorptive capacity of phosphate (phosphate Tm) was also evaluated in five additional dogs. During ECVE, phosphate excretion increased both in normal and thyroparathyroidectomized dogs, and a direct and significant correlation was found between the fractional excretion of phosphate and sodium. Despite a substantial decrease in filtered phosphate which is produced by the acute reduction in glomerular filtration rate, phosphate excretion, during ECVE, exceeded control values. ECVE was associated with a reduction in phosphate Tm. The results demonstrate that ECVE increases phosphate excretion independent of changes in glomerular filtration rate and parathyroid gland activity. The data indicate that ECVE produced by saline infusion decreases the renal tubular reabsorption of phosphate.     

Renal and hormonal actions of atrial natriuretic peptide during angiotensin II or noradrenaline infusion in man

In order to study the renal and hormonal actions of atrial natriuretic peptide (ANP) during background infusions with angiotensin II (ANG II) or noradrenaline (NA), 69 healthy subjects were examined in three main groups receiving a 90-min infusion with either placebo, ANG II (1.5 ng kg^?1 min^?1), or NA (25 ng kg^?1 min^?1). Each of these three main groups were subdivided into two groups receiving an infusion with either placebo or ANP (10 ng kg^?1 min^?1) for the last 60 min of the background infusion. Lithium clearance was used to evaluate segmental tubular reabsorption. ANG II alone caused a decrease in glomerular filtration rate (GFR), renal plasma flow, urinary absolute and fractional excretion of sodium, both proximal and distal fractional tubular sodium reabsorption, and urinary flow. NA alone caused a decrease in renal plasma flow. ANP alone caused a decrease in renal plasma flow. Urinary absolute and fractional excretion of sodium were increased and the distal fractional tubular reabsorption of sodium decreased, whereas the proximal fractional tubular reabsorption was unchanged by ANP. ANG II + ANP: during a background ANG II infusion, ANP still increased fractional excretion of sodium. Proximal fractional reabsorption was decreased, whereas distal fractional reabsorption of sodium was unchanged by ANP during ANG II infusion. The ANP-induced decreases in proximal absolute (?147 vs. +714 μmol min^?1 1.73 m^?2P = 0.05) and fractional (?1.7% vs. +0.6%, P<0.01) tubular sodium reabsorption were more pronounced, and the decrease in distal fractional tubular reabsorption of sodium (?0.1% vs. ?1.4%, P<0.05) less pronounced compared with when ANP was given alone. NA + ANP: during a background NA infusion, ANP still increased urinary sodium excretion and decreased distal fractional reabsorption. None of the ANP-induced absolute changes seen during background infusion with NA were significantly different from the ANP-induced changes seen during placebo background infusion. It is concluded that the natriuretic action of low-dose ANP seems to be preserved during background infusions with ANG II and NA in man. Net sodium excretion during the combined infusion with ANG II and ANP seems to reflect the sum of the opposing influences of each peptide. Low-dose ANP had a very modest but significant inhibitory effect on proximal tubular sodium reabsorption prestimulated by ANG II infusion.     

Abnormal proximal tubular sodium handling in normotensive patients with chronic glomerulonephritis and normal glomerular filtration rate

In 11 normotensive patients with biopsy verified chronic glomerulonephritis and 14 controls, glomerular filtration rate (GFR), proximal and distal tubular handling of sodium determined by the lithium clearance technique, and overall tubular sodium handling determined by absolute and fractional sodium excretion were measured before, during and after intravenous infusion of a 2.5% sodium chloride solution. Patients and controls were comparable by means of GFR in that no significant differences were found between the two groups either before, during or after sodium chloride infusion. During infusion both groups responded by a decrease in GFR (p less than 0.01 in both groups). Patients exhibited an increased natriuretic response during infusion both when measured as absolute and fractional sodium excretion (p less than 0.05 both). During the infusion the increase in absolute proximal output and decrease in fractional proximal and distal tubular sodium reabsorption were more pronounced in patients than in controls (p less than 0.05). It is concluded that patients with chronic glomerulonephritis at a very early stage of the disease where blood pressure and GFR are still normal respond with exaggerated natriuresis to hypertonic sodium chloride infusion. The exaggerated natriuresis is due to a decreased fractional proximal tubular sodium reabsorption in response to sodium loading.     

Effects of Felodipine on the dog kidney: a lithium clearance study.

This study was performed in order to investigate the possible influence of sympathetic nerve activity on the effects of the dihydropyridine calcium antagonist felodipine on absolute and fractional reabsorption rates of sodium and water in proximal and distal tubular segments in the dog kidney. Clearance of 51Cr-EDTA was used as a measure of glomerular filtration rate (GFR). GFR, urinary excretion rates of sodium and water, and lithium clearance (C-Li) were used for assessing the absolute and fractional tubular reabsorption rates. Felodipine infusion into the right renal artery increased renal vascular conductance (renal blood flow divided by renal arteriovenous pressure gradient) significantly (by 9%) while GFR remained unchanged. Calculated absolute proximal reabsorption rates remained unchanged while distal sodium reabsorption rate increased significantly from 2.1 +/- 0.3 to 2.7 +/- 0.4 mmol min-1. Sodium clearance (C-Na) increased from 0.22 +/- 0.08 to 0.40 +/- 0.07 ml min-1. The alpha-adrenergic blockade with phentolamine did not affect renal haemodynamic or excretory variables, nor did it influence the haemodynamic response to felodipine. After alpha-adrenergic blockade felodipine caused an increase in C-Na from 0.28 +/- 0.06 ml min-1 to 0.63 +/- 0.04 ml min-1, which was significantly greater than that measured after felodipine alone. The distal load (C-Li) was not significantly different from that obtained after felodipine alone, but distal sodium reabsorption rate increased less significantly after alpha-adrenergic blockade. The results suggest that felodipine, by its effect on tubular flow and/or composition, activates local alpha-adrenergic reflex mechanism(s), which stimulates distal sodium reabsorption, thereby attenuating the natriuretic effect.     

Sodium and water excretion in nephrotic patients: effects of changes in renal haemodynamics

1. Eight nephrotic patients were studied in order to evaluate the effects of acute changes in renal plasma flow and glomerular filtration rate on renal solute and water handling, in the absence of plasma volume expansion. 2. The subjects were studied first after the administration of captopril, a manoeuvre that increased renal plasma flow without a significant change in glomerular filtration rate, and a second time after receiving combined therapy with captopril and ibuprofen, a manoeuvre that decreased glomerular filtration rate without a significant change in renal plasma flow. 3. After captopril therapy, despite the increase in renal plasma flow, there was no significant change in proximal sodium reabsorption (as estimated from fractional lithium reabsorption), urine volume or urine osmolality. 4. The decrease in glomerular filtration rate observed after the administration of captopril plus ibuprofen was associated with decreases in fractional excretion of sodium and urine volume, and an increase in urine osmolality. The changes in these parameters of tubular function were proportionate to the changes in glomerular filtration rate. Fractional proximal sodium reabsorption increased substantially. 5. These observations suggest that, in the absence of plasma volume expansion, an increase in renal plasma flow does not increase sodium or water excretion by the nephrotic kidney. Moreover, during acute decreases in glomerular filtration rate, glomerulotubular balance appears to be disrupted, resulting in disproportionately high rates of proximal tubule sodium reabsorption.     

Micropuncture study of hypertonic mannitol diuresis in the proximal and distal tubule of the dog kidney

Fractional reabsorption of water, sodium, and potassium at proximal and distal tubular sites within the nephron was studied by recollection-micropuncture experiments on dogs undergoing hypertonic mannitol diuresis. After an initial control hydropenic phase, 16% mannitol in modified Ringer's solution was administered intravenously, resulting in marked increases in fractional excretion of water (28.7%), sodium (12.6%), and potassium (63.9%). Inulin clearance decreased significantly from 35.1 to 25.2 ml/min. Analysis of paired micropuncture data revealed a significant decrease in tubule fluid to plasma (TF:P) inulin ratios in both the proximal tubule (1.63-1.45) and distal tubule (5.38-1.94). There was also a significant decrease in proximal TF:P sodium ratios (0.99-0.93) and potassium ratios (1.05-0.98). Distal TF:P sodium ratios, in contrast, rose significantly (0.38-0.59), while TF:P potassium ratios tended towards unity whether initially greater or less than one. Fractional reabsorption of sodium and water decreased by 5% and 10% respectively in the proximal tubule, but to a lesser extent than the resulting increases in fractional urinary excretion. The nonreabsorbed fraction, however, had increased sharply at the point of distal puncture for water (32%), sodium (26%), and potassium (26%), indicating a large inhibitory effect within the loop of Henle in addition to the smaller proximal effects.     

Increased sodium reabsorption in the proximal and distal tubule of caval dogs

The effects of water diuresis, hypotonic NaCl, and hypotonic mannitol diuresis on renal sodium and water excretion were examined in normal dogs and in dogs with chronic constriction of the thoracic inferior vena cava and ascites (caval dogs). During all three diuretic states, the capacity to excrete solute-free water relative to the supply of sodium to the water clearing segment of the nephron was significantly greater in the caval dog. This finding was most evident during hypotonic NaCl diuresis but was also striking during hypotonic mannitol diuresis despite the more unfavorable gradient for sodium reabsorption at the distal tubule produced by this agent in caval dogs. In addition, fractional distal sodium load was significantly smaller in caval dogs during water diuresis and could not be increased as readily as in normal dogs by hypotonic NaCl or mannitol infusion. The data indicate that fractional sodium reabsorption is increased at the water clearing segment and the proximal tubule in caval dogs.     

Lithium clearance in chronic nephropathy

1. Lithium clearance measurements were made in 72 patients with chronic nephropathy of different aetiology and moderate to severely reduced renal function. 2. Lithium clearance was strictly correlated with glomerular filtration rate, and there was no suggestion of distal tubular reabsorption of lithium or influence of osmotic diuresis. 3. Fractional reabsorption of lithium was reduced in most patients with glomerular filtration rates below 25 ml/min. 4. Calculated fractional distal reabsorption of sodium was reduced in most patients with glomerular filtration rates below 50 ml/min. 5. Lithium clearance data were independent of whether renal disease was of primarily glomerular or tubular origin and, further, were not influenced by long-term conventional antihypertensive treatment. 6. It is concluded that, even with a reduced kidney function, the data are compatible with the suggestion that lithium clearance may be a measure of the delivery of sodium and water from the renal proximal tubule. With this assumption it was found that adjustment of the sodium excretion in chronic nephropathy initially takes place in the distal parts of the nephron (loop of Henle, distal tubule and collecting duct). With more severe impairment the proximal tubule also becomes involved in the adjustment.     

The acute effect of acetazolamide on glomerular filtration rate and proximal tubular reabsorption of sodium and water in normal man

The acute effects on kidney function of acetazolamide (250 mg) given intravenously were evaluated in seven healthy subjects. Glomerular filtration rate was measured as the renal clearance of 51Cr-EDTA, and fluid flow rate out of the proximal tubules was assessed by measurement of the renal lithium clearance. An 18% decline in glomerular filtration rate (ml/min) was observed after acetazolamide administration (109 +/- 16 vs 89 +/- 14, p less than 0.02), while lithium clearance (ml/min) increased by 35% (30 +/- 5 vs 38 +/- 8, p less than 0.02). Absolute proximal tubular reabsorption of water (ml/min) was reduced by about one third (79 +/- 12 vs 51 +/- 9, p less than 0.02), and fractional proximal reabsorption of water and sodium (%) declined (73 +/- 2 vs 58 +/- 6, p less than 0.02). Renal sodium clearance and absolute distal reabsorption of sodium increased, while fractional distal reabsorption of sodium declined. Acetazolamide reduces absolute and fractional proximal tubular reabsorption of sodium and water, and glomerular filtration rate. Primarily, this induces an increase in the output of fluid from the proximal tubules accounting for the diuretic effect of the drug. The acute fall in glomerular filtration rate is probably mediated by a temporary increase in proximal intratubular pressure and activation of the tubuloglomerular feedback mechanism.     

Intrarenal mechanisms of salt retention after bile duct ligation in rats.

In order to study renal salt-retaining mechanisms during the early stages of ascites formation, rats were subjected to bile duct ligation. After this procedure, plasma volumes were found to be reduced and hematocrits slightly increased. The whole-kidney glomberular filtration rate and plasma flows were reduced to 59 and 57% of control values, but the filtration fraction was unchanged. Absolute sodium excretion, as well as the fraction of the filtered sodium load excreted, was also significantly reduced. When micropuncture techniques were used to examine the function of single superficial nephrons, the glomerular filtration rate in these nephrons was found to be reduced to 70% of controlled values, and fractional reabsorption was found to be increased at all accessible sites along the nephron. Filtration by intermediate and juxtamedullary nephrons, determined by Hanssen's technique, was reduced to 55 and 48% of control values. By the use of radioactive microspheres, it was demonstrated that blood flow to superficial, intermediate, and juxtamedullary nephrons was reduced to 49, 59, and 73% of control values. Filtration by superficial nephrons decreased much more than plasma flow--a finding which suggests that the measured increase in fractional reabsorption was associated with an increase in the superficial nephron filtration fraction. From this study, it appears that two factors play an important part in the sodium retention observed in the initial stages of ascites formation following bile duct ligation in rats: (a) a decrease in the filtered sodium load and (b) increased fractional reabsorption by the superficial nephrons--the nephrons which show the least decrease in filtration.