Muzolimine: renal site of action and interaction with probenecid in humans.

Muzolimine (60 mg, administered orally) was administered to eight healthy volunteers, under conditions of altered fluid load, to elucidate its renal site of action. The duration of action and the effect of probenecid pretreatment on muzolimine response was also investigated. Muzolimine had a rapid onset of action, with the diuresis complete within 4 hours after dosing. At peak natriuresis, under hydrated conditions, fractional excretion of free water remained unaltered (9.72% +/- 0.59% versus 9.07% +/- 0.44%; difference not significant) but was accompanied by a significant increase in the delivery of sodium out of the proximal tubule, as measured by fractional excretion of lithium (22% +/- 2% to 31% +/- 1%; p less than 0.01). The fraction of sodium reabsorbed in the distal tubule also decreased from 94% +/- 1% to 67% +/- 1% (p less than 0.001) of the delivered load. The fractional reabsorption of free water during hydropenia decreased after muzolimine (5.63% +/- 0.26% to 2.00% +/- 0.81%; p less than 0.05). Pretreatment with probenecid resulted in a prominent decrease in urinary sodium excretion (246 +/- 25 mmol/24 hr for muzolimine alone 161 +/- 24 mmol/24 hr for muzolimine and probenecid; p less than 0.01). These findings suggest that muzolimine has a major site of action in the medullary portion of the thick ascending limb of Henle with additional inhibitory activity on the proximal tubule. It is likely that the active secretion of one or more of the acidic metabolites of muzolimine, by way of the probenecid sensitive organic acid pathway, is responsible for mediating the renal actions this basic drug.

Renal actions of piretanide and three other "loop" diuretics.

Thirty-nine clearance studies were performed in 17 healthy subjects under conditions of maximal hydration or hydropenia to compare the effects on renal solute and water handling of three sulfamoylbenzoic acid derivatives-piretanide, bumetanide, and furosemide-and the phenoxyacetic acid diuretic ethacrynic acid. Except for furosemide, which caused a 7% fall in effective renal plasma flow (ERPF), and ethacrynic acid, which reduced both the glomerular filtration rate (16%) and ERPF (23%) during maximal hydration, changes in hemodynamics were insignificant. At peak saluresis piretanide induced a mean reduction of -18.3% +/- 4.9% in fractional free-water clearance during hydration and -73.2% +/- 5.9% in fractional free-water reabsorption during hydropenia. The other sulfamoylbenzoates lowered fractional clearance and reabsorption of free water to similar extents, implying a major site of action within the medullary portion of the ascending limb. Ethacrynic acid reduced fractional free-water clearance to a greater degree than did the sulfamoylbenzoates. The mean reduction in fractional free-water reabsorption after ethacrynic acid (71.4% +/- 8.2%) was of the same order as that caused by the sulfamoylbenzoates. Similar excretory maxima for sodium, chloride, potassium, calcium, and magnesium were achieved for all four diuretics. Except for piretanide under hydropenia, sulfamoylbenzoate action did not change urinary pH. Ethacrynic acid consistently lowered urinary pH. During hydration piretanide induced phosphaturia (35.3% +/- 8.8%) and uricosuria (40.9% +/- 9.1%). Both bumetanide and piretanide increased fractional urate clearance during hydropenia (16.7% +/- 5.6% and 34.2% +/- 10.5%). There were no changes in phosphate or urate excretion after ethacrynic acid. Our data support the view that sulfamoylbenzoate diuretics exert additional effects on proximal tubular segments that are not shared by ethacrynic acid. Renal responses to piretanide most closely resemble those to bumetanide.

The influence of nonsteroidal anti-inflammatory drugs and probenecid on the renal response to and kinetics of piretanide in man.

The mechanism by which nonsteroidal antiinflammatory drugs interfere with the action of loop diuretics is not clear. We studied the renal response to an acute challenge of piretanide superimposed on pretreatment with either placebo, probenecid, indomethacin, or piroxicam in seven maximally hydrated subjects. No change was seen in glomerular filtration rate, as measured by creatinine clearance, throughout the experiments. When compared with responses to piretanide challenge after placebo pretreatment, probenecid reduced by 65% the peak fractional excretion of sodium (FENa), with a corresponding reduction in diuretic excretion. Pretreatment with indomethacin reduced peak FENa by 35%, but urinary delivery of piretanide was not altered. In contrast, piroxicam did not influence FENa but significantly reduced the delivery of both sodium and piretanide into urine. We conclude that the activity of nonsteroidal antiinflammatory drugs within the renal tubule varies among individual drugs and cannot be explained solely by their common mechanism of antiinflammatory action.

Foscarnet-induced changes in plasma concentrations of total and ionized calcium and magnesium in HIV-positive patients.

The time course and magnitude of foscarnet-induced changes in plasma concentrations of total and ionized calcium and magnesium were investigated in 13 male HIV-positive patients who had no active cytomegalovirus-associated disease. The patients had a mean age of 36 years (range 25-49 years) and a mean CD4 cell count of 550 cells/mm3 (range 130-1280 cells/mm3). Peak (mean +/- SD) plasma concentrations of foscarnet (0.89+/-0.10 mmol/l) were seen at the end of the period of drug infusion (90 mg/kg of foscarnet was infused over 2 hours) and declined with a terminal half-life of 5.7+/-0.7 hours. Plasma concentrations of total calcium declined over an 8-hour period, with the lowest concentration occurring after 4 hours (baseline: 2.29+/-0.09 mmol/l; lowest: 2.18+/-0.07 mmol/l; P < 0.001). By contrast, the lowest plasma concentration of ionized calcium occurred after 2 hours (baseline: 1.25+/-0.04 mmol/l; lowest: 0.99+/-0.05 mmol/l; P < 0.001), before gradually recovering to baseline levels over the next 10 hours. The mean maximal decrease in total calcium was 0.11+/-0.06 mmol/l, compared with 0.26+/-0.04 mmol/l for ionized calcium (P < 0.001). Plasma concentrations of total magnesium declined from 0.79+/-0.06 mmol/l (baseline) to 0.74+/-0.04 mmol/l (P < 0.05) after 4 hours and remained at this level after 8 hours. However, plasma concentrations of ionized magnesium fell steeply from 0.56+/-0.03 mmol/l to 0.39+/-0.03 mmol/l at 2 hours (P < 0.001), followed by a gradual recovery over the next 10 hours. The mean maximal decrease in total magnesium was 0.05+/-0.08 mmol/l, compared with 0.18+/-0.03 mmol/l (P < 0.001) for ionized magnesium. In summary, we found that foscarnet-induced changes in the plasma concentrations of total calcium and magnesium were dissociated from the corresponding changes in ionized calcium and magnesium. The maximal decreases in the plasma concentrations of total calcium and magnesium were smaller in magnitude and occurred much later than did the changes in ionized calcium and magnesium. The relative changes in the plasma concentration of ionized magnesium were greater than those of ionized calcium, indicating that foscarnet binds preferentially to the magnesium ion.

The effects of enalapril on blood pressure and the kidney in normotensive subjects under altered sodium balance.

Eight healthy volunteers received both oral enalapril (EN; MK-421) 20 mg and placebo (PL) under stable conditions of sodium repletion, 300 mmol sodium/day (HS) and sodium depletion, 10 mmol sodium/day (LS). During PL therapy, fivefold increases in the plasma concentrations of renin and aldosterone were observed when measurements under LS were compared with those under HS conditions. Basal blood pressure (BP) readings were consistently higher and the hypotensive response to EN greater under LS compared with HS conditions. After EN, renal plasma flow increased significantly over the first 4 h, while the glomerular filtration rate, measured both by inulin and creatinine clearances, did not change. A significant natriuretic response was observed within 2 h; further natriuresis between 6 and 12 h after EN was accompanied by increased phosphate excretion.

Pharmacokinetics and hemodynamic effects of single oral doses of thalidomide in asymptomatic human immunodeficiency virus-infected subjects.

Thalidomide (alpha-N-phthalimidoglutarimide), a potent inhibitor of tumor necrosis factor alpha (TNF-alpha), is proving to be a promising drug in the treatment of a number of inflammatory, autoimmune, and HIV-associated disorders. The pharmacokinetics and hemodynamic effects of two single oral doses of thalidomide (100 and 200 mg) were investigated, using a randomized, two-period crossover design, in a group of asymptomatic, male HIV-seropositive subjects. Thalidomide pharmacokinetics were linear at the doses studied, and were best described by a one-compartment model with first-order absorption and elimination processes. The drug was rapidly absorbed, with a mean absorption half-life of 0.95 hr (range, 0.16-2.49 hr) and 1.19 hr (range, 0.33-3.53 hr) after 100- and 200-mg doses, respectively. The corresponding mean Cmax values were 1.15+/-0.24 microg/ml (100 mg) and 1.92+/-0.47 microg/ml (200 mg; p<0.001), which were achieved (Tmax) at 2.5+/-1.5 h and 3.3+/-1.4 hr, respectively. Plasma concentrations of thalidomide declined thereafter, in a log-linear manner, with elimination half-lives of 4.6+/-1.2 hr (100 mg) and 5.3+/-2.2 hr (200 mg). The apparent volumes of distribution (Vdss/F) were 69.9+/-15.6 liters (100 mg) and 82.7+/-34.9 liters (200 mg) while total body clearances (Cl/F) were 10.4+/-2.1 and 10.8+/-1.7 liters/hr, respectively. Significant dose-dependent decreases in supine systolic and diastolic blood pressures were seen for up to 2 hr postdosing; somnolence, headache, dizziness, and confusion were also reported more frequently at the higher dose of thalidomide.

Effect of salt balance on the renal and hemodynamic actions of benazepril in normal men.

Renal and hemodynamic effects of diet alone and of single oral doses of the nonsulphydryl angiotensin converting enzyme (ACE) inhibitor, benazepril (10 mg), were investigated in eight healthy volunteers under stable conditions of high salt intake (300 mmol NaCl/day) and low salt intake (10 mmol NaCl/day), in a double blind, placebo controlled study. There were no changes in blood pressure between the two dietary extremes either during the run-in period or once sodium balance had been achieved. Mean renal plasma flow was higher, by approximately 10% and renal vascular resistance lower by 15%, on high salt diet compared to low salt diet. Glomerular filtration rates were found to be similar irrespective of the state of salt balance. Both plasma urate concentration and plasma renin activity were significantly elevated in the low salt compared to high salt state. Benazepril caused a greater fall in blood pressure in the sodium depleted state. Significant increases in the mean renal plasma flow, in the order of 15-20%, were seen over 6 h postbenazepril when compared with placebo response, regardless of the level of salt intake. Glomerular filtration rate over the same period remained unaltered. Benazepril doubled the urinary excretion of sodium over the first 4 hours after dosing whilst on the low salt diet; the equivalent increase during salt loading was approximately 20%. These results suggest that benazepril may exert direct effects on renal tubular function additional to those achieved through ACE blockade.

Possible differences in alpha-adrenoceptors in rabbit ileum and spleen.

In isolated tissues from reserpinized rabbits (5 mg kg-1, i.m. 20 h before experiment) and in the presence of cocaine (3 x 10(-5) M), corticosterone (2.8 x 10(-5)M), tropolone (3 x 10(-5) M), propranolol (4 x 10(-5)M) and disodium EDTA (3 X 10(-5)M), the potency ratios (relative to (-)-noradrenaline) of (-)adrenaline, (-)-phenylephrine and (+/-)-methoxamine were (m+/-s.e.) 2.03 +/- 0.13, 0.045 +/- 0.003 and 0.0062 +/- 0.0018 respectively in splenic strips and 1.77 +/- 0.41, 0.093 +/- 0.018 and 0.029 +/- 0.004 respectively in isolated ileum. Although the pA2 values for phentolamine and thymoxamine against (-)-noradrenaline in the two tissues were very similar there was a statistically significant difference when using yohimbine as the alpha-adrenoceptor blocking agent (pA2 = 6.80 +/- 0.30 in spleen; 5.60 +/- 0.12 in ileum). These differences suggest that the alpha-adrenoceptor in the two tissues is not identical. The pA2 value of phentolamine in rabbits ileum was not significantly different whether (-)noradrenaline or (+/-) methoxamine was used as agonist (7.91 +/- 0.07 and 7.97 +/- 0.06 respectively) while that of yohimbine was 5.56 +/- 0.10 using (-)noradrenaline and 6.19 +/- 0.12 using (+/-)methoxamine. In the light of this latter result and, considering the scatter of the experimentally determined values, there may be two alpha-adrenoceptors in rabbit ileum and either or both may not be identical in all respects to the alpha-adrenoceptor found in rabbit spleen.

Kinetic and metabolic aspects of enalapril action.

Enalapril is a long-acting, sulphydryl-free, ACE inhibitor whose humoral and hypotensive effects are maximal at 4-8 h and remain detectable at 24 h after a single dose. Serum profiles after chronic dosing of enalapril show little accumulation of the active diacid metabolite, enalaprilat. Comparison between the observed and predicted steady-state urinary recoveries of enalaprilat yields an effective accumulation half-life of approximately 11 h. In normotensive subjects, enalapril increases renal blood flow whilst leaving glomerular filtration unchanged irrespective of the state of sodium balance. Similarly under conditions of salt loading and salt depletion, a biphasic saluretic response is seen which parallels the excretory maxima for unchanged enalapril (1-2 h) and enalaprilat (4-8 h) suggesting direct interference by the drug moieties with tubular NaCl reabsorption. During the period of maximal enalapril action, uricosuria and phosphaturia are seen, supporting a direct action of enalaprilat on proximal tubular handling of these anions. Detailed documentation of the chronic metabolic effects of enalapril remains incomplete. A small rise in plasma potassium concentrations can occur but overt hyperkalaemia is unlikely in the absence of gross renal failure. Continued dosing is associated with a fall in plasma uric acid concentrations; plasma prolactin concentrations remain unaltered.

Renal handling of lithium and the effects of mannitol and arginine vasopressin in man.

1. A study has been undertaken in six healthy male subjects to clarify whether post-proximal segments of the nephron contribute to the renal handling of lithium under conditions of maximal forced osmotic load diuresis and arginine vasopressin-induced antidiuresis. Increments in the fractional clearance of free water, as a measure of effect at the proximal tubule, were positively correlated with incremental changes in flow rate, factored for glomerular filtration rate (mean r = 0.80 +/- 0.12, P < 0.001), and fractional excretion of lithium (mean r = 0.84 +/- 0.06, P < 0.001). Changes in flow rate and fractional excretion of lithium were also closely correlated with one another (mean r = 0.81 +/- 0.06, P < 0.001), and the mean slope of these regression lines was not significantly different from unity (1.18; 95% confidence interval 0.76-1.59). These results show that, under conditions of maximal hydration, mannitol-induced changes in proximal tubular function were closely correlated with induced changes in the fractional excretion of lithium. 2. Infusion of arginine vasopressin alone (0.5 m-units/min) caused a marked reduction in both fractional clearance of free water (10.7% +/- 1.2% to -1.2% +/- 0.2%, P < 0.001) and flow rate factored for glomerular filtration rate (14.0 +/- 1.5 to 0.8 +/- 0.2%; P < 0.001) while the fractional excretion of lithium showed only a small non-significant decrease (25.3% +/- 2.0% to 23.3% +/- 2.2%). A similar dissociation was noted between fluid and lithium excretion when arginine vasopressin was superimposed on mannitol infusion with reductions in the fractional clearance of free water (12.7% +/- 1.0% to -0.9% +/- 0.7%, P < 0.001) and flow rate (18.6% +/- 1.5% to 5.7% +/- 1.0%; P < 0.001), while the fractional excretion of lithium showed a significant increase (28.4% +/- 1.7% to 33.1% +/- 2.4%; P < 0.05). The lack of correlation between fluid and lithium excretion, in the presence of arginine vasopressin with or without mannitol, indicates that the late distal tubule and collecting duct have little or no significant capacity to reabsorb lithium. 3. These findings, taken as a whole, strengthen the view that renal tubular handling of lithium is primarily a proximal event.

Analysis of the natriuretic action of a loop diuretic, piretanide, in man.

1. The renal responses to a loop diuretic, piretanide, were investigated in a group of fourteen healthy volunteers. The effect of fluid replacement on the drug-response relationship was evaluated in the absence and in the presence of probenecid pretreatment following both oral and intravenous administration of piretanide. 2. Urinary excretion of piretanide was greater when volume losses were replaced than in the absence of volume replacement (i.v. dose: 3.32 +/- 0.15 vs 2.55 +/- 0.23 mg 6 h-1, P less than 0.01; oral dose: 2.57 +/- 0.09 vs 1.87 +/- 0.27 mg 6 h-1, P less than 0.01). With intravenous piretanide urinary excretion of sodium was likewise greater in the fluid replaced group (198 +/- 4 vs 141 +/- 10 mmol 6 h-1, P less than 0.01); these differences caused by fluid replacement did not however occur after oral dosing of piretanide (181 +/- 12 vs 167 +/- 14 mmol 6 h-1). 3. Probenecid pretreatment significantly decreased the renal excretion of piretanide in all subjects and consistently decreased the natriuretic response with the exception of intravenous piretanide challenge in subjects not undergoing fluid replacement. In this situation, despite probenecid causing a decrease in the amount of drug excreted (2.55 +/- 0.23 vs 1.63 +/- 0.15 mg 6 h-1, P less than 0.05) the sodium output was unaltered (141 +/- 10 vs 152 +/- 16 mmol 6 h-1, NS). 4. Complete replacement of the induced fluid losses resulted in the enhancement of the renal response, without affecting the shape of the diuretic response curve, of either the intravenous or orally administered piretanide.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetic and pharmacodynamic actions of enalapril in humans: effect of probenecid pretreatment.

The pharmacokinetic and pharmacodynamic profiles of oral enalapril (20 mg), in absence and in presence of probenecid pretreatment (1 g twice daily for 5 days), were investigated in 12 healthy volunteers on normal salt intake (150 mmol/24 hr). Mean peak serum concentration of enalapril rose from 158 +/- 7 to 216 +/- 1 ng/ml (P less than .01), whereas that of its metabolite, enalaprilat, rose from 62 +/- 6 to 84 +/- 8 ng/ml (P less than .01) in the presence of probenecid pretreatment. Area under the curve of both enalapril and enalaprilat increased by 50% (P less than .001), which was accompanied by a reduction in renal excretion of both compounds. The renal clearance of enalapril decreased from 229 +/- 19 to 61 +/- 4 ml/min (P less than .001) and that of enalaprilat from 108 +/- 4 to 66 +/- 2 ml/min (P less than .001). The total drug recovery fell from 48 +/- 3 to 38 +/- 2% (P less than .01) of the administered dose with no accompanying changes in plasma elimination half-lives of the parent drug or metabolite. The pharmacodynamic response of enalapril such as fractional excretions of sodium, calcium, magnesium and urate were enhanced by probenecid pretreatment. Absolute urinary excretion of sodium increased from 51 +/- 5 to 91 +/- 8 mmol/6 hr (P less than .001) after enalapril and from 55 +/- 4 to 113 +/- 13 mmol/6 hr (P less than .01) after enalapril in presence of probenecid pretreatment, despite a significant decrease in the renal excretion of enalapril and enalaprilat over the same interval.(ABSTRACT TRUNCATED AT 250 WORDS)

Natriuretic effect of caffeine: assessment of segmental sodium reabsorption in humans.

In order to assess the intrarenal mechanisms responsible for the natriuretic action of caffeine, the renal clearances of (51)Cr-EDTA [used as a measure of glomerular filtration rate (GFR)] and lithium (used as an index of end-proximal fluid delivery) were measured in eight healthy males before (control period) and immediately after (experimental period) a 400 mg oral dose of caffeine (given over 90 min) or placebo. In caffeine-treated subjects, the fractional excretion of sodium rose from 1.00+/-0.25% in the control period to 1.47+/-0.18% in the experimental period, while corresponding values on the placebo day were 1.04+/-0.16% and 0.70+/-0.07% respectively. GFR was unchanged following either caffeine or placebo. When compared with the placebo day, caffeine caused increases in lithium clearance (experimental period values: caffeine, 37+/-1 ml/min; placebo, 28+/-2 ml/min; P <0.001), the fractional excretion of lithium (caffeine, 34+/-1%; placebo, 26+/-2%; P <0.001) and the sodium/lithium clearance ratio (used as an index of the fraction of sodium delivered to the distal nephron that escapes reabsorption therein: caffeine, 4.4+/-0.3%; placebo, 2.8+/-0.2%; P <0.001). These results suggest that reduced fractional sodium reabsorption in both the proximal tubule and the distal nephron contributes to the acute natriuretic effect of caffeine. The data also confirm the importance of controlling caffeine intake when investigating renal function using lithium clearance.

Acute and long-term renal and metabolic effects of piretanide in congestive cardiac failure.

1. The renal and metabolic effects of the sulphamoylbenzoic acid diuretic, piretanide, have been studied, under controlled dietary conditions, in 39 patients with congestive cardiac failure. 2. In acute studies, peak saluresis occurred within 4 h of oral piretanide administration; saluresis was complete within 6 h, after which a significant antidiuretic effect was observed. Addition of triamterene, 50 mg, blunted the 0-6 h kaliuretic effect of piretanide. Over 24 h, piretanide, alone, caused insignificant urinary losses of potassium when compared with control. 3. In comparative studies, the piretanide dose-response curve was found to be parallel to that of frusemide over the dose range studied. The 0-6 h saluretic responses of piretanide, 6, 12 and 18 mg, were found to be equivalent to frusemide, 40, 80 and 120 mg respectively. The collective mean ratios of all the saluretic responses to each dose of piretanide with the corresponding dose of frusemide was observed to be 0.99 +/- 0.12, over 0-6 h period, and 0.86 +/- 0.09 over the 24 h period. The relative potency of piretanide, when compared with frusemide was found to be 6.18 (95% confidence limits 4.87-8.33), over the 0-6 h period, and 4.73 (95% confidence limits 3.65-6.14), over 24 h period. 4. In 15 patients in severe cardiac failure, urinary recovery of piretanide, over first 6 h, at the start of treatment was 21.2 +/- 2.1% while efficiency of the diuretic (mmol Na/mg drug) was 47.3 +/- 4.1. Long-term piretanide therapy was continued in the same group for up to and in some cases over 3 years. No other diuretics or potassium supplements were given. Piretanide dosage ranged from 6 to 24 mg day-1 according to clinical need. Plasma potassium fell significantly at 12 and 24 months, though remaining within the normal range. At these same times, significant elevations in both plasma urate and total fasting cholesterol were observed. Two patients developed overt gout on high dose piretanide therapy (24 mg day-1). Piretanide was well tolerated, and effective in the management of congestive cardiac failure without any other recognized metabolic or electrolyte changes.

Stereo-specificity of diuretic receptors in the nephron: a study of the enantiomers of indacrinone (MK-196) in man.

Urinary clearance techniques have been employed to compare the renal sites of action of three phenoxyacetic acid diuretics in man: ethacrynic (etacrynic) acid and the two enantiomers of indacrinone (MK-196). The effects of these compounds on fractional free-water clearance and reabsorption during maximal hydration and hydropenia, respectively, indicate that whilst ethacrynic acid and (-)-indacrinone have their natriuretic site of action in the medullary portion of the thick ascending limb of Henle's Loop, the (+)-enantiomer of indacrinone acts in the 'cortical diluting segment' or early distal tubule. The natriuretic potencies of all three agents are different as is their effect on the renal handling of uric acid. Ethacrynic acid produces minor urate retention whilst both enantiomers of indacrinone produce uricosuria and hypouricaemia. The apparent difference in the renal sites of action of the enantiomers of indacrinone is discussed in relation to our current knowledge of stereo-selectivity in other pharmacological systems.

Effect of maximal hydration on the renal responses to pretreatment with nonsteroidal anti-inflammatory drugs and probenecid in man.

The renal response to a challenge of maximal water diuresis has been studied in seven subjects pretreated over 48 h with either placebo, probenecid, indomethacin or piroxicam. Probenecid did not alter the excretion of water and sodium chloride when compared with placebo responses, but increased both phosphate and urate clearances. Indomethacin reduced significantly both water and sodium chloride clearances by approximately 40%. Piroxicam reduced water excretion to a similar extent but did not influence salt output. In parallel with these changes, both drugs caused significant phosphaturia. It is concluded that the renal actions of nonsteroidal anti-inflammatory drugs (NSAIDs) are individually distinct and involve direct effects on tubular transport of ions and water to differing extents within both the proximal and distal portions of the nephron.

The effects of naproxen and sulindac on renal function and their interaction with hydrochlorothiazide and piretanide in man.

We have studied the effect of a single dose challenge of naproxen (500 mg) and sulindac (200 mg) on renal function in five volunteers, and the effect of a single dose challenge of the thiazide, hydrochlorothiazide (100 mg), and loop diuretic, piretanide (6 mg) on renal function when the diuretics were given alone or when superimposed on chronic therapy of either naproxen or sulindac. None of the nonsteroidal anti-inflammatory drug (NSAID) or diuretic exposures significantly influenced glomerular filtration rate, as measured by creatinine clearance. Over the first 4 h of the study, both naproxen and sulindac reduced fractional excretion of sodium by approximately 50%. Sulindac also caused a significant uricosuria whilst naproxen promoted urate retention. Similar changes were observed over 8 h. Superimposition of either hydrochlorothiazide or piretanide on top of chronic sulindac therapy resulted in a blunting of the natriuresis by approximately 30% compared to when these diuretics were given alone: the action of the diuretics was unchanged by naproxen. Sulindac pretreatment did not alter the urinary excretion of either hydrochlorothiazide or piretanide; naproxen did not alter hydrochlorothiazide excretion. On the basis of these findings, it is concluded that NSAIDs exert direct tubular effects that do not necessarily interfere with the delivery of diuretics to their sites of action within the nephron.

Renal actions of a uricosuric diuretic, racemic indacrinone, in man: comparison with ethacrynic acid and hydrochlorothiazide.

The effects of indacrinone (IND) have been investigated in a two part study. First, a total of 36 clearance studies have been performed in 14 healthy volunteers, under conditions of either maximal hydration or hydropenia, to compare the renal sites of action of single oral doses of IND, 20 mg, ethacrynic acid (EA), 100 mg, and hydrochorothiazide (HCTZ), 100 mg. Under conditions of maximal water hydration, IND increased fractional Na+ excretion from a mean of 1.19 +/- 0.05 to 4.93 +/- 0.67% of GFR. This was similar to the response seen with HCTZ, which increased fractional Na+ clearance up to 3.16 +/- 0.17% of GFR; EA increased fractional Na+ excretion up to 14.5 +/- 2.5% of GFR. The mean reduction in fractional free-water clearance (CH2O/GFR X 100%) invoked by IND, (delta = -34.8% of control) was similar to that produced by EA, (delta = -27.2% of control), and by HCTZ, (delta = -26.6% of control). During hydropenia with superimposed mannitol diuresis, both IND and EA caused a fall in fractional free-water reabsorption (TcH2O/GFR X 100%), delta IND = -20.3% of control, delta EA = -70.1% of control. HCTZ produced a significant increase in fractional free-water reabsorption, delta HCTZ = -20.7% of control. In all studies, single doses of IND were both uricosuric and hypouricaemic. Fractional urate excretion increased from a mean 6.7 +/- 0.1 to 15.2 +/- 2.1% of GFR whilst plasma urate concentration fell from a mean of 0.36 +/- 0.03 to 0.34 +/- 0.03 mM (P less than 0.05) within 2-3 h post drug. HCTZ and EA, in single doses, had little effect on urate excretion. In the second part of the study, a total of 16 healthy volunteers received either IND, 10 mg, or HCTZ 50 mg, orally for 8 days, whilst on a diet of controlled electrolyte content. Both drugs were well tolerated by both sets of subjects with no adverse clinical or pathological findings. Both IND and HCTZ caused a significant reduction in weight and standing systolic blood-pressure during the first 48 h of therapy. At the doses administered, IND and HCTZ displayed similar diuretic responses with respect to water, Na+, Cl-, Ca2+ and PO4(3-) excretion. IND produced less kaliuresis than HCTZ during the first treatment day but cumulative K+ loss was similar for both drugs over the eight days of therapy. Fractional urate excretion after IND remained elevated throughout the 8 days of therapy and the subjects remained isouricaemic for 7 days.(ABSTRACT TRUNCATED AT 400 WORDS)

Renal responses and pharmacokinetics of piretanide in humans: effect of route of administration, state of hydration and probenecid pretreatment.

The influence of route of administration, state of hydration and transport inhibitor probenecid on the renal responses of a loop diuretic, piretanide, were investigated in 14 healthy volunteers. Maximally achieved plasma concentrations after i.v. and oral piretanide were higher in the nonhydrated state [+54% (i.v.); + 68% (oral)], accompanied by significant decreases in mean residence time, renal clearance and fraction of unchanged drug excreted with nonsignificant decreases in t1/2, steady-state volume of distribution and total clearance when compared with the hydrated state. Relative differences between the two hydrated states in maximal plasma concentrations of piretanide remained after probenecid [+26% (i.v.); +55% (oral)] but changes in kinetic parameters did not. Pretreatment with probenecid produced significant increases in absolute peak and plasma diuretic concentrations, t1/2 and mean residence time while decreasing steady-state volume of distribution, total clearance, renal clearance and fraction of unchanged drug excreted without affecting the bioavailability of piretanide. Urinary drug recovery was greater after i.v. than after oral piretanide, the recovery being consistently lower in nonhydrated state [iv: 2.78 (nonhydrated) versus 3.41 mg/24 h (hydrated); oral: 1.93 (nonhydrated) versus 2.76 mg/24 h (hydrated)]. Probenecid pretreatment reduced the overall urinary recovery of piretanide without altering the i.v./oral differences. Excretion of sodium paralleled piretanide excretion throughout the study except after i.v. dosing in the nonhydrated state where changes in drug excretion after probenecid (2.55 versus 1.63 mg/6 h) failed to influence sodium output (167 versus 152 mmol/6 h). These results demonstrate the importance of route of administration and state of hydration in determining the pharmacocological response of loop diuretics within the kidney.

The natriuretic effect of lithium in man: is the proximal tubule involved?

The possible role of the proximal tubule in the natriuresis which follows the administration of small doses of lithium, as used in lithium clearance studies, was investigated in 12 healthy males on a fixed sodium intake. Subjects were given placebo tablets, or 100 mg or 600 mg of lithium carbonate; renal function was assessed 3-6 h later. The 600-mg dose of lithium carbonate caused a 50-60% increase in sodium excretion, whereas the 100-mg dose was without effect. Creatinine clearance, used as an index of glomerular filtration rate, was unaffected by either dose. Three indices of end-proximal fluid delivery were used simultaneously: urine flow rate during suppression of vasopressin secretion (Vmax), phosphate clearance and lithium clearance (the latter only on the days on which lithium was administered). No effect of either dose of lithium on Vmax or phosphate clearance was evident; nor was there a difference between values for lithium clearance following the two doses. We conclude that administration of the standard 600-mg test dose of lithium carbonate does not affect proximal tubular function.