Inhibition of kidney function after blockade of thromboxane synthetase by imidazole in anaesthetized rats

Experiments on anaesthetized female Wistar rats have shown that imidazole reduces renal excretion of p-aminohippurate (PAH). This effect occurs only after administration of imidazole simultaneously with a volume load (2 ml/100 g b.wt.). Injection of imidazole immediately before a PAH bolus (100 mg/100 g b.wt. in 2 ml) is followed by reduced PAH excretion via urine for at least 1 hour. In contrast, if a PAH bolus is given 20 min or later after imidazole no effect of this drug on renal PAH transport is demonstrable. These findings indicate that imidazole can interfere effectively with thromboxane synthesis only if thromboxane production is activated by volume expansion. Interestingly, despite 40% reduction of renal PAH excretion in volumen loaded rats, PAH serum disappearance is identical in controls and imidazole treated rats. Thus differences in the volume of distribution for PAH after imidazole must be expected. Under our experimental conditions imidazole was without effect on renal electrolyte excretion.     

Dose response relation of the renal effects of PGA1, PGE2, and PGF2α in dogs

The effects of the three prostaglandins A₁, E₂, and F_2α on renal blood flow, glomerular filtration rate (GFR), fluid excretion, and urinary output of Na, K, Ca, Cl, and solutes were evaluated at a dose range of 0.01 – 10 μg/min. The prostaglandins were infused into the renal artery of dogs. GFR was not significantly altered by the PGs. PGA₁ increased renal blood flow by approximately of the control at 0.01 μg/min without dose dependence at higher infusion rates. It had only little effects which were not dose dependent on fluid and electrolyte output. The effects of PGE₂ on renal blood flow, fluid, sodium, and chloride excretion were dose dependent with a steep slope of the dose response curve between 0.1 and 1.0 μg/min. Blood flow was increased maximally by 80 %, urine volume by more than 400 %. PGF_2α had no effect on renal blood flow, whereas urinary output was increased to approximately the same maximal level as by E₂ although ten times higher doses were needed. Potassium excretion was less influenced than the excretion of Na and Cl and osmolar clearance was less increased than urine volume by all three prostaglandins.It is concluded that if a PG is involved in the regulation of the renal fluid or electrolyte excretion it is likely to be of the PGE-type. A PGA could only be involved in regulation of renal hemodynamics, whereas PGF although effective in the kidney exerts its effects at doses too high to have physiological significance.     

Atrial natriuretic factor inhibits vasopressin secretion in conscious sheep

To test the hypothesis that atrial natriuretic factor (ANF) has a centrally mediated action on body fluid homeostasis, the effects of intracerebroventricularly (ICV) infused ANF on plasma vasopressin (AVP) concentration and urinary water and electrolyte excretion were investigated in euhydrated and water-deprived conscious sheep. ICV ANF decreased plasma AVP concentration and increased urinary free water excretion in euhydrated sheep, with excretion of Na and K unaltered. However, ICV ANF did not affect urinary volume, free water clearance, or excretion of Na and K in dehydrated animals, although plasma AVP concentration was significantly decreased. The relationship between urine volume and plasma AVP concentration was fitted by a power curve: urine volume = 0.79 X [AVP]-0.71; urine volume changes very little as a function of AVP concentration at the higher ranges. Intravenous infusion of the same amount of ANF was without effect on plasma AVP concentration or urinary excretion in both euhydrated and dehydrated animals. Mean arterial pressure was unchanged throughout all experiments. These results are consistent with the hypothesis that central ANF inhibits AVP secretion.     

Renal effects of administered atrial natriuretic peptide in the conscious, aging rat

Studies were performed in conscious, chronically catheterized male Sprague-Dawley rats to investigate the effect of administered atrial natriuretic peptide (ANP) on blood pressure, renal hemodynamics and urinary electrolyte excretion. Studies were performed on young adult (3-4 month old) rats and on aging rats (18-24 months of age). Low dose ANP (80 ng/kg/min for 60 min) had no effects on renal hemodynamics in either young or old rats and produced only a slight blood pressure reduction in young animals. No effect on urinary electrolyte excretion was evident in young rats whereas in the old animals, low dose ANP produced large rises in the rate of sodium excretion, fractional excretion of sodium and urine flow rate. A four fold higher dose of ANP evoked a moderate natriuretic and a marked antihypertensive response in young rats. Time control studies indicated that time alone had no influence on urinary sodium excretion rate, the fractional excretion of sodium or urine flow rate. These studies indicate a much enhanced sensitivity to the natriuretic effects of administered ANP by the kidneys of old rats.     

The effect of infusion of hypertonic saline on glomerular filtration rate and arginine vasotocin, prolactin and aldosterone in the domestic chicken

Domestic fowl were infused for 60 min with isotonic saline followed by 90 min with hypertonic saline. Plasma electrolyte concentrations, osmolality and haematocrit were measured. Urine electrolyte excretion rates, osmolar output and urine flow rates were also monitored. From these results fractional excretions of electrolytes were calculated. The renal function markers inulin and ρ-amino hippuric acid were infused to enable the measurement of glomerular filtration rate and plasma clearance of ρ-amino hippuric acid, respectively. Plasma samples were also taken to assay for the hormones prolactin, aldosterone and arginine vasotocin. Plasma electrolytes and osmolality, fractional excretion of electrolytes and osmolar output all increased, while haematocrit decreased, throughout the experiment. However, no significant change was found in urine flow rate and little change was seen in glomerular filtration rate. The clearance of ρ-amino hippuric acid, which provides an indication of renal plasma flow, increased during hypertonic saline infusion. Plasma concentrations of aldosterone and prolactin decreased during the experiment and plasma concentrations of arginine vasotocin increased. Infusion of hypertonic saline had no consistent effect on glomerular filtration rate, which may be due to conflicting influences of expansion of the extracellular fluid volume and increased plasma osmolality. Accepted: 19 January 1998     

Effect of prostaglandin inhibition on glomerular filtration rate in normal and uremic rabbits

Studies were performed to assess the effect of alterations in prostaglandin biosynthesis on glomerular filtration rate in rabbits with normal renal function and after surgical reduction of renal mass. In normal animals, the administration of either of two cyclo-oxygenase inhibitors resulted in a 53% reduction in urine prostaglandin E excretion, but no change in creatinine clearance. Creatinine clearance rates were almost 71% lower in the uremic animals when compared to the animals with normal renal function. Despite the reduction in renal mass, urine prostaglandin E excretion rates in the uremic animals were over twice that seen in normal rabbits. When factored by either glomerular filtration rate or remaining renal mass, urine prostaglandin E excretion rates in uremic rabbits when compared to normal animals were increased more than 9-times and 4-times respectively. Administration of cyclo-oxygenase inhibitors in the uremic animals resulted in a 71% decrease in urine prostaglandin E excretion and, unlike the non-uremic animals, a 53% fall in creatinine clearance. These findings suggest that intact renal prostaglandin biosynthesis is a necessary factor in the homeostatic adaptive mechanisms which maintain the glomerular filtration rate in animals with decreased renal mass.     

Renal effects of dopamine and ANP in high volume expanded rats

Both dopamine (DA) and atrial natriuretic peptide (ANP) have been postulated to exert similar effects on the kidney, participating in the regulation of body fluid and sodium homeostasis. In the present study, experiments were performed in anesthetized and isotonic sodium chloride volume expanded rats. After acute volume expansion at 15 % of body weight during 30 min, glomerular filtration rate, urine output, sodium excretion, fractional sodium excretion, proximal and distal sodium excretion and blood pressure were measured. In additional groups we administered ANP or haloperidol or the combination of both to volume expanded animals. Blockade of DA receptors with haloperidol, attenuated diuretic and natriuretic responses to volume load. Proximal sodium excretion was not modified by haloperidol in all experimental groups of rats. Reduction in distal tubular excretion was induced by haloperidol in saline infusion expanded rat but not in ANP treated expanded animals. In conclusion, when exaggerated volume expansion is provoked, both DA and ANP exert renal tubular events, but ANP have a major central role in the regulation of renal sodium handling.     

The effects of clonidine on the kidney function in the anesthetized dog

Studies were performed to determine the mechanism by which the antihypertensive agent clonidine increased urine flow. The response of the kidney has been examined in four combinations. The parameters of renal function have been compared during volume expansion by 1.5-2.0% body weight Ringer solution. In the control animals, volume expansion by 2% body weight, resulted in a slight increase in sodium excretion and urine flow. In 10 anesthetized dogs 1.0 microgram/kg/min of clonidine infused i.v. during 30 minutes (the total amount of clonidine infused was 30 micrograms/kg) decreased the arterial blood pressure from 136 +/- 13 mmHg to 127 +/- 12 mmHg and elevated urine flow from 2.95 +/- 1.65 ml/min to 4.34 +/- 1.77 ml/min while the urine osmolality diminished from 399 +/- 107 mosm/l to 265 +/- 90 mosm/l and the glomerular filtration remained constant. In 5 animals 0.1 microgram/kg/min of clonidine was infused into the left renal artery (this dose is corresponding to the renal fraction of the cardiac output) without any effects in the left kidney. 1.0 microgram/kg/min of clonidine infused directly into the left renal artery produced vasoconstriction in the ipsilateral kidney, decreased the glomerular filtration rate and the urine flow. By contrast in the right kidney the urine flow rose without hemodynamic changes, and the urine osmolality became hypoosmotic compared to the plasma. In ten dogs 1.0 microgram/kg/min of clonidine and 1 mU/kg/min of arginine-vasopressin were infused intravenously. The vasopressin infusion superimposed on the clonidine could not inhibit the increase of the urine excretion, and the fall of the urine osmolality. The results suggest that the clonidine increases the renal medullary blood flow possibly via a direct mechanism, decreases the sympathetic outflow to the kidney and via an indirect pathway, mediated by the renin-angiotensin system. The renal medullary flow increase produces a washout of the medullary osmotic gradient, and the water reabsorption diminishes.     

Renal clearance and excretion of endogenous substances in the owl monkey

The clearance and excretion of creatinine, calcium, phosphorus, sodium, and potassium by the kidney was evaluated in 62 owl monkeys using timed urine collections and quantitative urinalyses. The endogenous clearance of creatinine was determined for each monkey. Urinary electrolyte excretion and fractional electrolyte excretions (FE) were measured. Linear regression analysis was used to calculate the correlation between urinary excretion and FE for each electrolyte. The coefficient of determination for each analyte was significant (P ? .0001). Determination of FE was found to be an appropriate indicator of the renal handling of electrolytes and, when viewed in conjunction with urinalysis and other serum parameters, an aid in evaluating renal function in the owl monkey. © 1992 Wiley-Liss, Inc.     

Renal handling and acute urinary electrolyte effects of aminoglycoside antibiotics: Use of a solitary renal autotransplant in the conscious sheep

Renal handling of the aminoglycoside antibiotics gentamicin and tobramycin were studied before and after one hour of constant intravenous infusions adjusted to maintain a concentration of 15 μg/mL. A solitary renal autotransplant model in four conscious volume replete 40 Kg sheep was used. This unique surgical preparation allows sampling of renal arterial and renal venous blood as well as urine drained through an exteriorized parotid-ureteral fistula. This surgical preparation has considerable potential in renal pharmacology since it uses a conscious, large animal. Baseline studies in this preparation demonstrated normal, ⁵¹CrEDTA and ¹²⁵I PAH, clearances which were unaffected by the drugs. Aminoglycoside binding to pooled sheep sera was 11% at physiologic PH. calcium and magnesium concentrations. A–V difference was 1.3 ± .3 μg/mL and extraction by the kidney was 9 ± 3.2% with no differences between gentamicin and tobramycin. Clearance of gentamicin was 84% and tobramycin 86% of GFR. There was no evidence of tubular injury as evidenced by unchanged urinary beta-2 microglobulin excretion. Serum Na, K, Ca and Mg did not change over the course of the study. Both drugs caused a prompt decrease in absolute and fractional sodium excretion while only gentamicin produced a kaliuresis. Early aminoglycoside effects on electrolyte balance may be an eventual determinant of nephrotoxic potential rather than differences in renal drug handling.Nephrotoxicity is a major side effect of aminoglycoside antibiotic therapy. Although gentamicin and tobramycin have similar pharmacokinetics, including renal cortical accumulation, both double blind clinical studies (1) and experimental data (2) have shown that gentamicin is more frequently associated with renal dysfunction. Recent studies in the dog have suggested that hypokalemia due to renal potassium wasting is a risk factor predisposing to nephrotoxicity (3). In clinical usage aminoglycosides may induce hypokalemia and hypocalcemia, perhaps resulting from drug-induced magnesium depletion (4). Previous studies reporting data concerning the acute effects of aminoglycosides on renal function and electrolyte excretion have used anesthetized animals (5) or isolated perfused kidney preparations (6). The present experiments utilize a unique surgical preparation in which a solitary kidney is autotransplanted to the neck of a sheep followed by a contral ateral nephrectomy. Urine flow is exteriorized through a uretero-parotid-cutaneous fistula thus providing a conscious animal with ready access to renal arterial and renal venous blood. Our results show that renal handling of gentamicin and tobramycin do not differ during short-term constant infusions. Both drugs caused a decrease in sodium excretion while gentamicin caused a larger increase in fractional and absolute potassium excretion. This raises the possibility that nephrotoxic properties of aminoglycosides may be secondary to their effects on electrolytes.     

Water and electrolyte changes in skeletal and cardiac muscles of rats during prolonged hypokinesia

The objective of this study was to show that hypokinesia (diminished movement) could affect differently water and electrolyte content in muscles having minimum differences in their function and morphology. To this end, we studied water and electrolyte content in skeletal and cardiac muscles, fluid excretion, electrolyte absorption, and electrolyte levels in plasma, urine and feces of rats during prolonged hypokinesia (HK). Studies were conducted on one-hundred-twenty-six 13-weeks old male Wister rats during a pre-hypokinetic period and a hypokinesia period. Animals were equally divided into two groups: vivarium control rats (VCR) and hypokinetic rats (HKR). Hypokinetic animals were kept in small individual cages which restricted their movements in all directions without hindering food and water intake. Control rats were housed in individual cages under vivarium control conditions. Sodium (Na+) and potassium (K+) absorption, electrolyte and water content in cardiac muscles (right and left ventricle), thigh extensor (quadriceps femoris muscle) and long muscle of the back (biceps femoris muscle), urine volume, and electrolyte levels in plasma and urine and feces did not change in VCR when compared to their pre-hypokinetic levels. The absorption of Na+ and K+, water and electrolyte content in cardiac and skeletal muscles decreased significantly, while urine volume, plasma electrolyte levels and urine and fecal electrolyte excretion increased significantly in HKR compared with their pre-HK values and with their respective vivarium control (VCR). Water and electrolyte content decreased more significantly in skeletal than in cardiac muscles. Water and electrolyte levels decreased more in the thigh extensor and in the right ventricle than in the long muscle of the back, the left ventricle or the septum. Muscles suffering from higher water and electrolyte loss against the background of lower water and electrolyte content show lower water and electrolyte deposition. Lower electrolyte and water content in skeletal than in cardiac muscle shows that water and electrolyte content decreases more in skeletal than cardiac muscles. Skeletal muscle showed lower water and electrolyte content than cardiac muscle indicating that the risk for decreased muscle water and electrolyte content is inversely related to the muscle function and morphology, i.e., the more weight-bearing supporting function and morphology muscles have, the higher the risk for lower muscle water and electrolyte content. It was concluded that the greater muscle function and morphology, the lower electrolyte and water deposition, the higher water and electrolyte losses, and the lower water and electrolyte content.     

Kidney function in the Spinifex hopping mouse, Notomys alexis

Notomys alexis (Spinifex hopping mouse) is found in the arid zone of Australia. The structure and function of the kidneys allow this species to conserve water. This study investigated the rate at which N. alexis can reduce urine volume and increase the concentration of electrolytes and solutes when water deprived. It also looked at the response to rehydration, following a period of water deprivation. The laboratory mouse, Mus musculus domesticus, was used for comparison. N. alexis is able to reduce urine volume and increase urine concentration more rapidly than M. m. domesticus when water deprived. This appears to occur prior to any measurable changes in plasma electrolyte concentrations and is not due to reductions in glomerular filtration rate. Gradual water deprivation over a period of 10 days allowed N. alexis to adjust so that urine composition was similar in many ways to animals that had ad libitum access to water, whereas M. m. domesticus required significant water supplementation to maintain body weight at 85% of initial body weight. Ability to concentrate urine rapidly is characteristic of a well-insulated renal medulla [Bankir, L., DeRouffignac, C., 1985. Urinary concentrating ability: insights from comparative anatomy. Am. J. Physiol. 249, R643-666]. However, a well-insulated medulla is normally associated with slow dilution of urine when animals are rehydrated. N. alexis was able to produce dilute urine very rapidly following rehydration of water deprived animals. Physiological control of renal function appears to be complex. Although M. m. domesticus is able to produce concentrated urine, it is unable to survive without free water and responds more slowly to water deprivation.     

The relationship between sodium excretion and renin secretion by the perfused kidney.

The effect of altered tubular sodium reabsorption on renin secretion (RSR) was examined under conditions in which other factors influencing renin release could be controlled or excluded. To do this, isolated canine kidneys were perfused at constant pressure with blood circulating from donor animals. Volume expansion or hemorrhage of the donor dogs produced large changes in the animal's blood pressure, renal function, sodium excretion (UNaV), and RSR, but were without effect on renal hemodynamics, UNaV, or RSR in the perfused kidney. Hemodilution without volume expansion, resulted in hypotension, decreased UNaV and increased RSR in the donor dogs, and increased UNaV and suppressed RSR in the perfused kidney. These effects of hemodilution in the perfused kidney were partially reversed when plasma protein concentration was restored to control levels with hyperoncotic albumin, and, overall, there was a significant inverse relationship between electrolyte excretion and RSR. These results provide new evidence for the hypothesis that the rate at which sodium is delivered to the macula densa is an important determinant of the rate of renin secretion.     

The influence of renal nerves on electrolyte excretion in conscious and anesthetized rats fed or fasted overnight

The role of the renal nerves in the electrolyte excretion of rats fed or fasted overnight was determined in conscious rats and anesthetized (Inactin) and surgically prepared rats. In conscious rats sodium excretion, as measured in a 1-h urine collection period after feeding or fasting overnight, was decreased with fasting with or without renal nerves. Renal nerve activity, as measured by norepinephrine turnover (inhibition of tyrosine hydroxylase by alpha-methyl-p-tyrosine), was not different between conscious fed or fasted rats and increased to the same extent in fed and fasted rats when anesthetized and surgically prepared. Anesthetized, surgically prepared rats infused with 5.0% glucose showed a denervation natriuresis if rats were fed overnight, but not if they had been fasted overnight. Potassium excretion in conscious and anesthetized rats was lower in fasted rats than fed rats with or without renal nerves. These data suggest (i) renal nerves are not involved in the renal response to an overnight fast in conscious rats, and (ii) in anesthetized, surgically prepared rat renal sympathetic tone is enhanced and denervation natriuresis occurs if rats are fed but not if fasted. Potassium excretion is a reflection of whether rats are fed or fasted and not whether they have renal nerves.     

Renal responsiveness to aldosterone during exposure to head-down tilt bedrest

The kidneys represent a fundamental organ system responsible in part for the control of vascular volume. A 10% to 20% reduction in plasma volume is one of the fundamental adaptations during exposure to low gravity environments such as bedrest and space flight. Bedrest-induced hypovolemia has been associated with acute diuresis and natriuresis. Elevated baseline plasma renin activity and aldosterone levels have been observed in human subjects following exposure to head-down tilt and spaceflight without alterations in renal sodium excretion. Further, attempts to restore plasma volume with isotonic fluid drinking or infusion in human subjects exposed to head-down bedrest have failed. One explanation for these observations is that renal distal tubular cells may become less sensitive to aldosterone following exposure to head-down tilt, with a subsequent reduction in renal capacity for sodium retention. We hypothesized that elevated sodium and water excretion observed during prolonged exposure to bedrest and the subsequent inability to restore body fluids by drinking might be reflected, at least in part, by reduced renal tubular responsiveness to aldosterone. If renal tubular responsiveness to aldosterone were reduced with confinement to bedrest, then we would expect measures of renal sodium retention to be reduced when a bolus of aldosterone was administered in head-down tilt (HDT) bedrest compared to a control experimental condition. In order to test this hypothesis, we conducted an investigation in which we administered an acute bolus of aldosterone (stimulus) and measured responses in renal functions that included renal clearances of sodium and free water, sodium/potassium ratio in urine, urine sodium concentration, and total and fractional renal sodium excretion.     

Influence of augmentation of excretory renal mass on renal function after alpha-receptor blockade

The effect of renal function of an augmentation of the excretory renal mass was investigated in 10 dogs without drug treatment and in 10 animals with alpha-receptor blockade. In the untreated group, augmentation of excretory renal mass by transplantation into the neck of one pair of kidneys isolated from another animal caused the following changes in the kidneys in situ: marked elevation in CPAH, slight decrease in Cinulin, slight diminution of urine excretion and a pronounced fall in sodium excretion. The amount of urine and sodium excreted by the four kidneys was identical with that previously excreted by the two kidneys in situ. In animals with alpha-receptor blockade, augmentation of the excretory renal mass had the following consequences in the in situ kidneys, CPAH, and Cinulin remained unchanged while urine and sodium excretion decreased to the same extent as in the untreated control group. The amount of urine and of sodium excreted by the four kidneys was the same as that excreted by the kidneys in situ, prior to transplantation of isolated kidneys, i.e. before the augmentation of excretory renal mass. It seems that the decrease in sodium excretion of the kidneys in situ was not due to the haemodynamic changes evoked by the load on the circulation; it was rather consequence of some quick, presumably humoral, regulation. The diminution of sodium excretion in the kidneys in situ after augmentation of the excretory renal mass has been ascribed to an increased utilization by the four kidneys of the natriuretic factor(s), i.e. to a diminution in the plasma level of the natriuretic hormone.     

A role for the angiotensin IV/AT4 system in mediating natriuresis in the rat

Angiotensin II (AngII) or Angiotensin IV (AngIV) was infused into the renal artery of anesthetized rats while renal cortical blood flow was measured via laser Doppler flowmetry. The infusion of AngII produced a significant elevation in mean arterial pressure (MAP) with an accompanying decrease in cortical blood flow, glomerular filtration rate (GFR), urine volume, and urine sodium excretion. The infusion of AngIV induced significant increases in renal cortical blood flow and urine sodium excretion, without altering MAP, GFR, and urine volume. Pretreatment infusion with a specific AT1 receptor antagonist, DuP 753, blocked or attenuated the subsequent AngII effects, while pretreatment infusion with the specific AT4 receptor antagonist, Divalinal-AngIV, blocked the AngIV effects. These results support distinct and opposite roles for AngII and AngIV, i.e. AngII acts as an anti-natriuretic agent, while AngIV acts as a natriuretic agent.     

The effects of hypophysectomy, prolactin therapy and environmental calcium on electrolyte balance of the brown trout Salmo trutta, L.

Adaptation of the brown trout to fresh water containing increasing concentrations of calcium resulted in a decrease in plasma electrolyte level and total electrolyte excretion. The electrolyte excretion rate was higher at the beginning than at the end of the urine collection periods. Hypophysectomized fish had a lower plasma electrolyte concentration than the controls. This deficiency was partially corrected by polactin therapy. High environmental calcium was only effective to a limited extent. There was no difference in the normal renal sodium output between hypophysectomized and intact fish in fresh water. Environmental calcium did not have any significant effect on renal electrolyte output of hypophysectomized fish.     

Effects of atrial natriuretic factor on the cardiovascular system and several parameters of renal excretory function in spontaneously hypertensive rats

The influence of atrial natriuretic factor on several parameters of cardiovascular system and renal excretory function in spontaneously hypertensive rats has been investigated. The exogenously administered atrial natriuretic factor, not influencing the arterial pressure level and electrolyte concentration in the urine, at the same time breaks the links between APmax and the intensity of electrolyte excretion in urine.     

Influence of renal denervation on renal effects of acute nitric oxide and ETA/ETB receptor inhibition in conscious normotensive rats.

The role of renal nerves in the effects of concomitant NO synthase and non-selective ET(A/)ET(B) receptor inhibition on renal function was investigated in conscious normotensive Wistar rats. NO synthase inhibition alone (10 mg/kg b. w. i.v. L-NAME) in sham-operated rats with intact renal nerves induced an increase in systolic, diastolic and mean arterial pressure, urine flow rate, sodium, chloride and calcium excretion (p<0.05). The effect of L-NAME was markedly reduced by bosentan (10 mg/kg b.w. i.v.) and the values of urine flow rate, sodium, chloride and calcium excretions returned to control level (p<0.05). L-NAME administration one week after a bilateral renal denervation increased blood pressure to a similar extent as in sham-operated rats but decreased urine flow rate (p<0.05) and did not change electrolyte excretion. ET(A/)ET(B) receptor inhibition with bosentan during NO synthase inhibition in the renal denervated rats did not produce changes in urine flow rate or electrolyte excretion. NO synthase inhibition as well as concurrent NO synthase and ET(A/)ET(B) receptor inhibition did not change clearance of inulin or paraaminohippuric acid in sham-operated or renal denervated rats. These results indicate that renal sympathetic nerves play an important modulatory role in NO and endothelin induced effects on renal excretory function.