Clearance Of Furosemide Research Articles

7-Hydroxycoumarin and its conjugated metabolites interact with organic anion transporters 1 and 3 in vitro and in vivo.

7-Hydroxycoumarin (7-HC) is a natural coumarin compound rich in Chinese herbal medicines and has various pharmacological activities. After oral administration of 7-HC in rodents, its conjugated metabolites 7-hydroxycoumarin-β-D-glucuronide (7-HCG) and 7-hydroxycoumarin sulfate (7-HCS), exhibit high systemic exposure and urinary excretion. Organic anion transporters 1 and 3 (OAT1 and OAT3), mainly expressed in the proximal renal tubules, play an important role in drug-drug interactions and drug-induced kidney injury. We aimed to explore the mechanisms of OAT-mediated drug interactions and renal protective mechanisms of 7-HC and its conjugates. OAT-overexpressing cell models revealed that 7-HC was not a substrate for OAT1 and OAT3, while 7-HCG was specifically transported by OAT3. In contrast, 7-HCS can be transported by both OATs. Besides, 7-HC significantly inhibited the activity of OAT1 and OAT3, while 7-HCS had a strong inhibitory effect on OAT1 (IC50<10 μM). After co-administration of 100 mg/kg of 7-HC to mice, systemic exposure and clearance of furosemide (a clinical substrate of OATs) were significantly increased and decreased, respectively. In addition, 7-HC decreased OAT-mediated cytotoxicity and reduced the renal distribution of adefovir in mice. Together, these findings will provide support for OAT-mediated drug interactions and the renal protection of 7-HC.

Effect of probenecid on blood levels and renal elimination of furosemide and endogenous compounds in rats: Discovery of putative organic anion transporter biomarkers

Transporter-mediated drug-drug interactions (DDIs) are assessed using probe drugs and in vitro and in vivo models during drug development. The utility of endogenous metabolites as transporter biomarkers is emerging for prediction of DDIs during early phases of clinical trials. Endogenous metabolites such as pyridoxic acid and kynurenic acid have shown potential to predict DDIs mediated by organic anion transporters (OAT1 and OAT3). However, these metabolites have not been assessed in rats as potential transporter biomarkers. We carried out a rat pharmacokinetic DDI study using probenecid and furosemide as OAT inhibitor and substrate, respectively. Probenecid administration led to a 3.8-fold increase in the blood concentrations and a 3-fold decrease in renal clearance of furosemide. High inter-individual and intra-day variability in pyridoxic acid and kynurenic acid, and no or moderate effect of probenecid administration on these metabolites suggest their limited utility for prediction of Oat-mediated DDI in rats. Therefore, rat blood and urine samples were further analysed using untargeted metabolomics. Twenty-one m/z features (out of >8000 detected features) were identified as putative biomarkers of rat Oat1 and Oat3 using a robust biomarker qualification approach. These m/z features belong to metabolic pathways such as fatty acid analogues, peptides, prostaglandin analogues, bile acid derivatives, flavonoids, phytoconstituents, and steroids, and can be used as a panel to decrease variability caused by processes other than Oats. When validated, these putative biomarkers will be useful in predicting DDIs caused by Oats in rats.

Metabolomic Profiling Identifies New Endogenous Markers of Tubular Secretory Clearance.

The proximal tubules eliminate protein-bound toxins and drugs through secretion. Measurements or estimates of GFR do not necessarily reflect the physiologically distinct process of secretion. Clinical assessment of this important intrinsic kidney function requires endogenous markers that are highly specific for secretory transport. We used metabolomics profiling to identify candidate markers of tubular secretory clearance in 50 participants from a kidney pharmacokinetics study. We measured metabolites in three sequential plasma samples and a concurrent 10-hour timed urine sample using hydrophilic interaction liquid chromatography/high-resolution mass spectrometry. We quantified the association between estimated kidney clearance and normalized plasma peak height of each candidate solute to the clearance of administered furosemide, a protein-bound, avidly secreted medication. We identified 528 metabolites present in plasma and urine, excluding pharmaceuticals. We found seven highly (>50%) protein-bound and 49 poorly bound solutes with clearances significantly associated with furosemide clearance and 18 solute clearances favoring an association with furosemide clearance by the 90th percentile compared with GFR. We also found four highly bound and 42 poorly bound plasma levels that were significantly associated with furosemide clearance. We found several candidate metabolites whose kidney clearances or relative plasma levels are highly associated with furosemide clearance, an avidly secreted tracer medication of the organic anion transporters, highlighting their potential as endogenous markers of proximal tubular secretory clearance.

Furosemide clearance in very preterm neonates early in life: A pilot study using scavenged samples

Furosemide is an off-label drug frequently used as a diuretic in neonates with oliguria and/or edema. Its clearance in preterm neonates is lower than in term neonates or children. We aimed herein to clarify furosemide clearance (CL) in very preterm (VP) neonates (< 28 weeks gestation) within the first two weeks of life and identify the factors predictive of the PK parameters, such as CL. Furosemide was administered at 0.5 or 1 mg/kg in a 0.5-h infusion via a syringe pump, and blood samples were drawn from an artery or vein after the intravenous injection. The serum furosemide concentration was measured using high-performance liquid chromatography. The PK parameters were then analyzed using Bayesian estimation. Thirteen blood samples were obtained from ten VP neonates after intravenous injection. The mean postconceptional age and mean postnatal days at exposure to furosemide was 26.9 weeks and 7.1 days, respectively. The estimated mean CL was 16.5 mL/kg/h. The mean distribution volume (Vd) and elimination half-life (t1/2) was 0.37 L/kg and 15.3 h, respectively. Furosemide CL was negatively associated with serum creatinine (SCr) [CL = 84.2 - 67.1 × SCr (mg/dL)]. VP neonates within the first two weeks of life had a higher CL than subjects in other preterm neonatal studies. The SCr level was the sole parameter influencing furosemide CL and might serve as a good index for furosemide dosing in VP neonates.

Prediction of Kidney Drug Clearance: A Comparison of Tubular Secretory Clearance and Glomerular Filtration Rate.

Although proximal tubular secretion is the primary mechanism of kidney drug elimination, current kidney drug dosing strategies are on the basis of eGFR. In a dedicated pharmacokinetic study to compare GFR with tubular secretory clearance for predicting kidney drug elimination, we evaluated stable outpatients with eGFRs ranging from 21 to 140 ml/min per 1.73 m2. After administering single doses of furosemide and famciclovir (metabolized to penciclovir), we calculated their kidney clearances on the basis of sequential plasma and timed urine measurements. Concomitantly, we quantified eight endogenous secretory solutes in plasma and urine using liquid chromatography-tandem mass spectrometry and measured GFR by iohexol clearance (iGFR). We computed a summary secretion score as the scaled average of the secretory solute clearances. Median iGFR of the 54 participants was 73 ml/min per 1.73 m2. The kidney furosemide clearance correlated with iGFR (r=0.84) and the summary secretion score (r=0.86). The mean proportionate error (MPE) between iGFR-predicted and measured furosemide clearance was 30.0%. The lowest MPE was observed for the summary secretion score (24.1%); MPEs for individual secretory solutes ranged from 27.3% to 48.0%. These predictive errors were statistically indistinguishable. Penciclovir kidney clearance was correlated with iGFR (r=0.83) and with the summary secretion score (r=0.91), with similar predictive accuracy of iGFR and secretory clearances. Combining iGFR with the summary secretion score yielded only modest improvements in the prediction of the kidney clearance of furosemide and penciclovir. Secretory solute clearance measurements can predict kidney drug clearances. However, tight linkage between GFR and proximal tubular secretory clearance in stable outpatients provides some reassurance that GFR, even when estimated, is a useful surrogate for predicting secretory drug clearances in such patients.

Furosemide as a functional marker of acute kidney injury in ICU patients: a new role for an old drug.

New pharmacokinetics insight suggests that the furosemide pharmacology occurring in ICU patients with AKI is similar, but not equal to that described in chronic stable renal patients. Even if the diuretic response to furosemide is expressed by a steep dose-response curve positively correlated with renal function, pharmacodynamic limitations occur when creatinine clearance is < 20ml/min or urine output is < 500ml/12h. In such cases, other factors specifically due to acute tubular injury can interfere with the furosemide-induced diuretic output. As modality of administration recent reports and metanalysis, even if not conclusive, suggest that for the same given dose a continuous infusion of furosemide was superior in diuretic response. For septic shock patients on CVVHDF where treatment adds an additional clearance of furosemide the maximum diuretic response is achieved by a continuous infusion of 20mg/h of furosemide. At this infusion rate the reached plasma level was < 20mg/L, a range considered safe and not ototoxic. Therefore, the severity of AKI establishes whether a patient will respond to furosemide. In this review we summarized all these recent updates, also suggesting that the diuretic response under continuous infusion may allow assessing glomerular and tubular functions with increased reliability than a bolus dose. However, validation studies are still needed to support continuous infusion as a stress test.

Population pharmacokinetic modeling of furosemide in patients with hypertension and fluid overload conditions

Furosemide is a loop diuretic drug frequently indicated in hypertension and fluid overload conditions such as congestive heart failure and hepatic cirrhosis. The purpose of the study was to establish a population pharmacokinetic model for furosemide in Indian hypertensive and fluid overload patients, and to evaluate effects of covariates on the volume of distribution (V/F) and oral clearance (CL/F) of furosemide. A total of 188 furosemide plasma sample concentrations from 63 patients with hypertension or fluid overload conditions were collected in this study. The population pharmacokinetic model for furosemide was built using Phoenix NLME 1.3 software. The covariates included age, sex, body surface area, bodyweight, height and creatinine clearance (CRCL). The pharmacokinetic data of furosemide was adequately explained by a two-compartment linear pharmacokinetic model with first-order absorption and an absorption lag-time. The mean values of CL/F and Vd/F of furosemide in the patients were 15.054 Lh-1 and 4.419 L, respectively. Analysis of covariates showed that CRCL was significantly influencing the clearance of furosemide. The final population pharmacokinetic model was demonstrated to be appropriate and effective and it can be used to assess the pharmacokinetic parameters of furosemide in Indian patients with hypertension and fluid overload conditions.

Robot-Assisted Pyeloureterostomy for Lower Pole Ureteropelvic Junction Obstruction in an Incomplete Duplicated System

Introduction: Ureteropelvic junction obstruction (UPJO) and duplicated collecting systems, complete or incomplete, are relatively common congenital urologic anomalies, but rarely occur together. UPJO in incomplete duplicated systems usually involves the lower pole moiety1,2 and patients can present with obstruction-related problems, including flank pain and upper urinary tract infection.3 We present a video-enhanced description of a robot-assisted pyeloureterostomy for a symptomatic right lower pole UPJO in an incomplete duplex system. The video outlines the initial presentation, provides all related radiologic investigations, details the surgical technique, and provides initial outcome data. Methods: A healthy 54-year-old woman presented with a 3-year history of intermittent right flank pain. All preoperative imaging studies confirmed the diagnosis of a right lower pole UPJO in an incomplete duplicated system. Renal scintigraphy revealed 53% right differential function and a furosemide clearance half-time of 145 minutes for the lower pole moiety. One week preoperatively, the patient's right upper pole (UP) moiety was stented to facilitate identification of the collecting system. After appropriate preparation of the patient, pneumoperitoneum was obtained using a Veress needle technique. The da Vinci© robot was docked after placement of all ports: a 12-mm camera, two 8-mm robotic and one 8-mm assistant ports. First, the right colon was mobilized to expose the retroperitoneum. To aid exposure, the overlying perinephric tissue was tacked laterally to the abdominal sidewall using Hem-o-Lok® clips. The bladder was filled with methylene blue-infused normal saline (methyleneNS), which easily refluxed into the UP, but did so very slowly into the lower pole moiety. This permitted easier identification of the dilated lower pole moiety with a narrowed entry point at the level of the bifurcation. We continued dissection to identify, but not devascularize, the common ureter and its bifurcation into the upper and lower pole moieties. Rather than excise the stenotic UPJ and perform an end-to-side anastomosis, a decision was made to perform a side-to-side anastomosis in an effort to minimize scarring of the common ureter. An incision was made on the cephalad aspect of the lower pole pelvis and the caudal aspect of the dilated UP moiety ureter. Using a 3-0 PDS suture, a side-to-side anastomosis was performed in a running fashion. The posterior layer of the pyeloureterostomy was closed first, from lateral to medial, followed by the anterior layer in a similar manner. Before completing the anastomosis, a 6F ureteric stent was inserted antegradely over a hydrophilic-tipped guidewire, next to the existing preoperative UP moiety stent. The anastomosis was then tested using retrograde infusion of methyleneNS. At the end of the procedure, a Jackson-Pratt drain was placed through the lower robotic port. Results: The surgical time was 127 minutes, estimated blood loss was 50 cc, and the patient was discharged on POD 2 with no postoperative complications. Both ureteric stents were removed 4 weeks postoperatively and 6 weeks later, renal scintigraphy demonstrated no evidence of obstruction with a significantly improved furosemide clearance half-time of 6 minutes. The patient remains pain free for 9 months postoperatively. Conclusion: Robot-assisted pyeloureterostomy for lower pole UPJO in an incomplete duplicated system is a safe and feasible option. No competing financial interests exist. Runtime of video: 6 mins 7 secs

Clinical consequences of the biphasic elimination kinetics for the diuretic effect of furosemide and its acyl glucuronide in humans.

This review discusses the possibility of whether furosemide acyl glucuronide, a metabolite of furosemide, contributes to the clinical effect of diuresis. First an analytical method (e.g. HPLC) must be available to measure both parent drug and furosemide acyl glucuronide. Then, with correctly treated plasma and urine samples (light protected, pH 5) from volunteers and furosemide-treated patients, the kinetic curves of both furosemide as well as its acyl glucuronide can be measured. The acyl glucuronide is formed in part by the kidney tubules and it is possible that the compound is pharmacologically active through inhibition of the Na+/2Cl-/K+ co-transport system; up to now the mechanism of action has been solely attributed to furosemide. The total body clearance of furosemide occurs by hepatic and renal glucuronidation (50%) and by renal excretion (50%). Enterohepatic cycling of furosemide acyl glucuronide, followed by hydrolysis, results in a second and slow elimination phase with a half-life of 20-30 h. This slow elimination phase coincides with a pharmacodynamic rebound phase of urine retention. After each dosage of furosemide, there is first a short stimulation of urine flow (4 h), which is followed by a 3-day recovery period of the body. The following clinical implications arise from study of the elimination kinetics of furosemide. Repetitive dosing must result in accumulation of the recovery period. Accumulation of furosemide and its acyl glucuronide in patients with end-stage renal failure results from infinite hepatic cycling. Impaired kidney function may result in impaired glucuronidation and diuresis. While kidney impairment normally requires a dose reduction for those compounds which are mainly eliminated by renal excretion, for diuretics, a dose increment is required in order to maintain a required level of diuresis. The full clinical impact of the accumulation of furosemide and its acyl glucuronide in patients with end-stage renal failure has to be determined.

Effects of cytochrome P450 inducers and inhibitors on the pharmacokinetics of intravenous furosemide in rats: involvement of CYP2C11, 2E1, 3A1 and 3A2 in furosemide metabolism

Abstract Objectives It has been reported that the non-renal clearance of furosemide was significantly faster in rats pretreated with phenobarbital but was not altered in rats pretreated with 3-methylcholanthrene. However, no studies on other cytochrome P450 (CYP) isozymes have yet been reported in rats. Method Furosemide 20 mg/kg was administered intravenously to rats pretreated with various CYP inducers –3-methylcholanthrene, orphenadrine citrate and isoniazid, inducers of CYP1A1/2, 2B1/2 and 2E1, respectively, in rats – and inhibitors – SKF-525A (a nonspecific inhibitor of CYP isozymes), sulfaphenazole, cimetidine, quinine hydrochloride and troleandomycin, inhibitors of CYP2C6, 2C11, 2D and 3A1/2, respectively, in rats. Key findings The non-renal clearance of furosemide was significantly faster (55.9% increase) in rats pretreated with isoniazid, but slower in those pretreated with cimetidine or troleandomycin (38.5% and 22.7% decreases, respectively), than controls. After incubation of furosemide with baculovirus-infected insect cells expressing CYP2C11, 2E1, 3A1 or 3A2, furosemide was metabolized via CYP2C11, 2E1, 3A1 and 3A2. Conclusions These findings could help explain possible pharmacokinetic changes of furosemide in various rat disease models (where CYP2C11, 2E1, 3A1 and/or CYP3A2 are altered) and drug–drug interactions between furosemide and other drugs (mainly metabolized via CYP2C11, 2E1, 3A1 and/or 3A2).

Effects of cytochrome P450 inducers and inhibitors on the pharmacokinetics of intravenous furosemide in rats: involvement of CYP2C11, 2E1, 3A1 and 3A2 in furosemide metabolism

It has been reported that the non-renal clearance of furosemide was significantly faster in rats pretreated with phenobarbital but was not altered in rats pretreated with 3-methylcholanthrene. However, no studies on other cytochrome P450 (CYP) isozymes have yet been reported in rats. Furosemide 20 mg/kg was administered intravenously to rats pretreated with various CYP inducers--3-methylcholanthrene, orphenadrine citrate and isoniazid, inducers of CYP1A1/2, 2B1/2 and 2E1, respectively, in rats--and inhibitors--SKF-525A (a non-specific inhibitor of CYP isozymes), sulfaphenazole, cimetidine, quinine hydrochloride and troleandomycin, inhibitors of CYP2C6, 2C11, 2D and 3A1/2, respectively, in rats. The non-renal clearance of furosemide was significantly faster (55.9% increase) in rats pretreated with isoniazid, but slower in those pretreated with cimetidine or troleandomycin (38.5% and 22.7% decreases, respectively), than controls. After incubation of furosemide with baculovirus-infected insect cells expressing CYP2C11, 2E1, 3A1 or 3A2, furosemide was metabolized via CYP2C11, 2E1, 3A1 and 3A2. These findings could help explain possible pharmacokinetic changes of furosemide in various rat disease models (where CYP2C11, 2E1, 3A1 and/or CYP3A2 are altered) and drug-drug interactions between furosemide and other drugs (mainly metabolized via CYP2C11, 2E1, 3A1 and/or 3A2).

NXY‐059 Does Not Significantly Interact With Furosemide in Healthy Volunteers

NXY-059 is a free radical-trapping neuroprotectant that reduces infarct size and preserves brain function in animal models of acute ischemic stroke. Acute ischemic stroke patients receiving NXY-059 may also be exposed to diuretics for treatment of heart failure or hypertension. NXY-059 and furosemide are partly eliminated by active tubular secretion via an organic anion transporter. This double-blind, randomized, crossover, placebo-controlled study investigated whether an infusion of NXY-059 (15 mg/mL) during 12 hours affects the diuretic and saluretic effects of a 30-mg intravenous bolus dose of furosemide (10 mg/mL) administered after 6 hours' infusion, in 13 male and 11 female healthy subjects. The net increase in urine volume and sodium excretion in the interval of 6 to 12 hours was 4.15 L and 178 mmol/L, respectively, during NXY-059 treatment (P = .93) and 4.34 L and 190 mmol/L, respectively, during placebo treatment (P = .54). NXY-059 reduced the renal clearance of furosemide by 19% (P = .019), and furosemide reduced the renal clearance of NXY-059 by 8% (P = .005). NXY-059 was well tolerated.

Genetic polymorphisms in the glucuronosyltransferases 1A1, 1A8 and 1A9 in relation to pharmacokinetics of furosemide

Background/Aims About 30% of the loop diuretic furosemide is eliminated via glucuronidation. According to in vitro data, uridine diphosphate glucuronosyltransferase (UGT) 1A8 may catalyze in this reaction but the quantitatively relevant isoenzyme in humans has not been unambiguously identified. We analyzed whether polymorphisms in UGT1A1, 1A8 and 1A9 are associated with the pharmacokinetics of furosemide. Methods In an open-label single dose study 93 healthy male volunteers got 80 mg furosemide and pharmacokinetics were measured over 24 hours after dosing. Polymorphisms in the UGT1A1, -1A8, and -1A9 genes were analyzed by pyrosequencing. Results Seven polymorphisms distributed over the UGT1A1 gene and 2 polymorphisms in the UGT1A8 and UGT1A9 genes were analyzed in correlation with furosemide total oral clearance. One C/T polymorphism in the intron 3 of the UGT1A1 gene was associated with furosemide clearance (p= 0.024) with a mean of 16.7, 17.2, and 22.3 L/h in CC, CT, and TT carriers, respectively. One A/T polymorphism at position −276 in the UGT1A9 promotor was also associated (p=0.049) with mean clearance of 18.0, 14.1, and 13.0 L/h in A/A, A/T, and T/T carriers. Significant associations with furosemide drug actions were not found. Conclusions There was a large interindividual kinetic and dynamic variability of furosemide in healthy volunteers and genetic polymorphisms in UGT enzymes may partially explain this variability. Clinical Pharmacology & Therapeutics (2005) 77, P34–P34; doi: 10.1016/j.clpt.2004.12.021

BUCOLOME, A POTENT BINDING INHIBITOR FOR FUROSEMIDE, ALTERS THE PHARMACOKINETICS AND DIURETIC EFFECT OF FUROSEMIDE: POTENTIAL FOR USE OF BUCOLOME TO RESTORE DIURETIC RESPONSE IN NEPHROTIC SYNDROME

To determine whether bucolome (5-n-butyl-1-cyclohexyl-2,4,6-trioxoperhydropyrimidine), a nonsteroidal anti-inflammatory agent, can reverse diuretic resistance of furosemide in patients with nephrotic syndrome, we examined the inhibitory effect of bucolome on the protein binding of furosemide in serum and urine. Bucolome significantly inhibited the protein binding of furosemide not only in serum but also in urine of preparation albumin (UPA), which mimics urinary albumin concentration in patients with nephrotic syndrome by ultrafiltration method. The binding percentage of furosemide to albumin was approximately 70% in UPA. With coadministration of bucolome to healthy volunteers, renal clearance of furosemide was increased, reflecting the increase of the free fraction of furosemide in serum. Furthermore, coadministration of bucolome caused a significant increase of urine volume and sodium concentration in urine. Even at higher urine levels of furosemide, the inhibitory effect of bucolome on the protein binding of furosemide in UPA remains constant, and changes in pH at weakly acidic pH levels (pH 5.5-6.5) did not alter the inhibitory effect of bucolome. Interestingly, coadministration of bucolome with furosemide in doxorubicin (Adriamycin)-induced nephrotic syndrome model rats alleviated the diuretic resistance. These results suggest that bucolome has a potent inhibitory effect on the protein binding of furosemide in the urine and can partially restore the diuretic response of furosemide in patients with nephrotic syndrome by increasing the free fraction of furosemide at the site of action.

Evaluation of dilated upper renal tracts by technetium-99m ethylenedicysteine f+0 diuresis renography in infants and children

To evaluate the feasibility of modifying diuresis renography by the simultaneous administration of Tc-99m ethylenedicysteine and furosemide in the investigation of hydronephrosis and hydroureteronephrosis in infants and children. Parameters assessed were the diuretic response in normal kidneys and the ability of the F+0 study to differentiate between renal obstruction and nonobstruction. One hundred and thirty-three children (93 males, 40 females; mean age 35.2 months) with sonographic diagnoses of hydronephrosis or hydroureteronephrosis underwent F+0 diuresis renography. Tc-99m ethylenedicysteine (3.7 MBq/kg body weight) and furosemide at an appropriate dose were administered intravenously at the start of the study. Posterior imaging of the kidneys and bladder was performed for 20 min followed by imaging after voiding. All patients were followed-up for 12 months, and the results of the initial F+0 diuresis renography were compared with the final diagnoses. Final diagnosis was based on the pediatric urologist's decision of either surgery or conservative management. A renal unit was defined as a kidney and its ureter. There were 262 renal units with 4 patients having a solitary kidney. 90 normal and 172 abnormal renal units on sonography were assessed by F+0 diuresis renography. The furosemide clearance half time for the 90 normal renal units was 5.8 +/- 1.4 min. Of the 172 abnormal renal units, 100 were classified as nonobstructed and 72 as obstructed on diuresis renography. All 100 nonobstructed renal units were correctly classified with no false-negative studies; of the 72 renal units classified as obstructed, there were 43 true-positive studies and 29 false-positive studies. The sensitivity was 100%, specificity was 78% and accuracy was 83%. Tc-99m ethylenedicysteine F+0 diuresis renography is a valid method for the investigation of hydronephrosis and hydroureteronephrosis in infants and children.

F+0 diuresis renography in infants and children

UNLABELLED The purpose of this study was to evaluate the feasibility of modifying diuresis renography by the simultaneous administration of 99mTc-mercaptoacetyltriglycine (MAG3) and furosemide in the investigation of hydronephrosis and hydroureteronephrosis in infants and children. Two parameters were assessed: the diuretic response in normal kidneys and the ability of the F+0 study to differentiate between renal obstruction and nonobstruction and to identify the level of obstruction in cases of renal obstruction. METHODS Seventy-two patients (48 males, 24 females; age 2 d to 7 y; median age 6 wk) with sonographic diagnoses of hydronephrosis or hydroureteronephrosis were reviewed prospectively over a 3-y period. All patients had prior sonographic studies and micturating cystourethrography. Bladder catheterization was not routinely performed and was undertaken only if the child had suspected vesicoureteric junction (VUJ) obstruction or grade II or more vesicoureteric reflux. A weight-adjusted dose of 99mTc-MAG3 (maximum 200 MBq, minimum 20 MBq) and 1 mg/kg of furosemide (maximum 40 mg) were administered intravenously at the same time. Posterior imaging of the kidneys and bladder was performed for 20 min and followed by gravity-assisted drainage or imaging after voiding. All patients were followed-up for 6-12 mo, and the final diagnoses were based on either surgery or conservative management with repeated sonography or follow-up 99mTc-MAG3 studies (or both). The results of the F+0 diuresis renography were then compared with the final diagnoses. RESULTS A renal unit was defined as a kidney and its ureter. There were 151 renal units with 1 patient having bilateral duplex kidneys, 6 patients having unilateral duplex kidneys and 1 patient having a solitary kidney. Fifty-five normal renal units and 96 abnormal renal units on the basis of sonographic findings were assessed. The furosemide clearance half-time for the 55 normal renal units was 1.3-6.3 min (mean 3.8 min). Of the 96 abnormal renal units, 53 were classified as nonobstructed and 43 were classified as obstructed. Of the 53 renal units classified as nonobstructed, there were 48 true-negative studies and 5 false-negative studies; of the 43 renal units classified as obstructed, there were 40 true-positive studies and 3 false-positive studies. The sensitivity was 88.9%, specificity was 94.1% and accuracy was 91.7%. The level of obstruction, either pelviureteric junction or VUJ, was also correctly identified. CONCLUSION F+0 diuresis renography shows excellent diuretic responses in normal kidneys and is a valid method for the investigation of hydronephrosis and hydroureteronephrosis in infants and children.

The influence of moderate hypoalbuminaemia on the renal metabolism and dynamics of furosemide in the rabbit.

1. The present study aimed to investigate the influence of hypoalbuminaemia on the pharmacokinetics and pharmacodynamics of furosemide. Hypoalbuminaemia was produced by repeated plasmapheresis, to attain plasma albumin concentrations of 21.6 +/- 0.9 g l-1, compared with 33.0 +/- 0.6 g l-1 in controls (P < 0.001). The per cent of bound furosemide in hypoalbuminaemic rabbits (90.8 +/- 0.7%) was lower than that in control rabbits (97.4 +/- 0.5%, P < 0.001). The kinetics of intravenous furosemide (2.5 mg kg-1) were studied in control (n = 6) and hypoalbuminaemic rabbits (n = 6). 2. To assess the effect of hypoalbuminaemia on extrarenal clearance of furosemide, functional anephria was induced by ligating the renal pedicles of 12 rabbits, which were segregated in two groups, with and without hypoalbuminaemia. 3. In the control group, total, urinary and metabolic clearances of furosemide were 11.8 +/- 1.0, 5.0 +/- 0.4 and 6.8 +/- 0.6 ml min-1 kg-1, respectively. Compared with control rabbits, in hypoalbuminaemic rabbits, total clearance of furosemide increased by 40% (P < 0.001), result of the enhancement of furosemide metabolic clearance (C1m) from 5 to 10 ml min-1 kg-1 (P < 0.01). In hypoalbuminaemic rabbits, urinary excretion of furosemide was reduced by 26% (2451 +/- 115 vs 1818 +/- 134 micrograms h-1, P < 0.01). In anephric rabbits, furosemide total clearance was 1.77 +/- 0.12 ml min-1 kg-1, value not affected by hypoalbuminaemia, confirming that the increase in C1m induced by hypoalbuminaemia occurs in the kidneys. 4. Compared with controls, in hypoalbuminaemic rabbits, the rate of urinary excretion (142 +/- 9 vs 74 +/- 8 ml h-1, P < 0.001) and the rate of excretion of sodium (18.6 +/- 0.9 vs 9.9 +/- 0.9 mmol h-1, P < 0.001) were very much reduced. However, the dose-response curves were not different. 5. In conclusion, hypoalbuminaemia is associated with an increase in renal metabolic clearance of furosemide, possibly because of the increase in furosemide unbound concentration, and a decrease in the diuretic/natriuretic effect of furosemide, secondary to a reduction in furosemide tubular secretion. Thus, albumin facilitates the renal secretion of organic anions but not their metabolism.

Role of the kidneys in the metabolism of furosemide: its inhibition by probenecid.

The site where furosemide is metabolized and the location where probenecid reduces furosemide metabolism remain poorly defined. The liver appears to play a minor role, and there is indirect evidence suggesting that the kidneys could be responsible for the metabolism of furosemide. To assess the role of the kidneys in the metabolism of furosemide, its intravenous kinetics have been studied in control and anephric rabbits, after the ligation of the renal pedicles. Two additional groups of rabbits, control and anephric, have received probenecid before the administration of furosemide. In the control group, the total clearance of furosemide was 18.65 +/- 1.01 mL/ min per kg; urinary and metabolic clearances of furosemide were 7.95 +/- 0.65 and 10.70 +/- 1.11 mL/min per kg, respectively. In anephric rabbits, total clearance was reduced by 85% to 2.69 +/- 0.26 mL/min per kg (P < 0.001), secondary to the abolition of furosemide renal excretion and to the reduction in metabolic clearance from 10.70 +/- 1.11 to 2.69 +/- 0.26 mL/min per kg (P < 0.001). The pretreatment with probenecid reduced the total clearance of furosemide by 80%, to 3.62 +/- 0.24 mL/min per kg (P < 0.001), because of a reduction of 90 and 75% in urinary and metabolic clearances, respectively. The administration of probenecid to anephric rabbits did not reduce further the metabolic clearance. It is concluded that the kidneys are responsible for 85% of furosemide total clearance, either via excretion (43%) or biotransformation (42%), and that probenecid inhibits both processes.

Response to furosemide during dehydration with and without naproxen pretreatment of kidney donors and renal transplant recipients

The response to 40 mg furosemide p.o. in 6 healthy kidney donors and 6 renal transplant recipients with and without naproxen pretreatment has been studied. No volume replacement was given in order to study the development of tolerance. The subjects showed an average dehydration of 1.5 kg.6 h-1. While mean creatinine clearance was equal in patients and donors (76 vs 80 ml/min), renal furosemide clearance was significantly lower in the patients (47 vs 81 ml min; P less than 0.05). The patients also excreted a smaller fraction of the dose in the urine (5.7 vs 7.8 mg/6 h; P less than 0.05). As the overall renal sensitivity was similar in the two groups, the natriuretic response was correspondingly smaller in transplant recipients as compared to donors. Within the observation period of 6 h after dosing, acute tolerance developed in the donors and in 4 of the 6 patients, as shown by clockwise hysteresis in the dose (urine furosemide excretion rate)-response (natriuresis) curves. Pretreatment with naproxen reduced renal sensitivity to furosemide (right shift of the dose response curve) in all the donors but in only 2 of the patients. In both groups acute tolerance was less pronounced after naproxen, which may indicate involvement of the prostaglandin system in the development of acute tolerance. The results may also indicate regeneration of sympathetic nerves with functional capacity in at least some renal transplants, or that other mechanisms of salt regulation compensate for loss of sympathetic nerve activity.

Inhibition of renal clearance of furosemide by pentopril, an angiotensin—converting enzyme inhibitor

The pharmacokinetic interaction between pentopril (250 mg) and furosemide (40 mg) was studied in 12 normal healthy volunteers after oral administration of each drug alone and in combination. No significant changes in any pharmacokinetic parameters of pentopril or its active metabolite (CGS 13934) were observed on coadministration of furosemide. In contrast, pentopril induced significant changes in disposition of furosemide. Pentopril decreased renal clearance (CLR) of furosemide by 54% and the fraction excreted unchanged in urine also decreased by 55%. However, such decrease in CLR of furosemide was compensated by a simultaneous increase in glucuronidation (by 200%), resulting in a slight increase in systemic clearance (decreased AUC). Systemic bioavailability of furosemide appears to be unchanged in the presence of pentopril (0.46 vs. 0.41). No effect of pentopril on plasma protein binding of furosemide was detected. In spite of the decreased CLR and urinary excretion rate of furosemide, the urinary output (1749 vs. 1774 ml/6 hr) and Na+ excretion (757 vs. 816 mEq/6 hr) remained almost unchanged. These findings suggest that total furosemide (unchanged and glucuronide) might contribute to diuresis and natriuresis rather than the unchanged furosemide alone. Because of unchanged pharmacodynamic effect, such pharmacokinetic interaction may not require any dosage adjustment for furosemide on pentopril coadministration.