Pharmacokinetics of intravenously administered bumetanide in man

Bumetanide Therapeutic Effect in Children and Adolescents With Autism Spectrum Disorder: A Review Study

Introduction:

Autism Spectrum Disorder (ASD) is characterized by several impairments in communications and social interactions, as well as restricted interests or stereotyped behaviors. Interventions applied for this disorder are based on multi-modal approaches, including pharmacotherapy. No definitive cure or medication has been introduced so far; therefore, researchers still investigate potential drugs for treating ASD. One of the new medications introduced for this purpose is bumetanide. The present article aimed to review the efficacy of this drug on the core symptoms of ASD and its potential side effects.

Methods:

We searched all papers reported on pharmacokinetics, pharmacodynamics, efficacy, and adverse effects of bumetanide on animal models and humans with ASD. The papers were extracted from the main databases of PubMed, Web of Science, and Scopus.

Results:

The findings revealed that cortical neurons have high Chloride ion (Cl−)i and excitatory actions of gamma-aminobutyric acid in the valproic acid animal model with ASD and mice with fragile X syndrome. Bumetanide, which has been introduced as a diuretic, is also a high-affinity-specific Na+−K+−Cl− cotransporter (NKCC1) antagonist that can reduce Cl− level. The results also indicate that bumetanide can attenuate behavioral features of autism in both animal and human models. Moreover, the studies showed that such medication could activate fusiform face area in individuals with ASD while viewing emotional faces. Also, recent findings suggest that a dose of 1 mg/d of this drug, taken twice daily, might be the best compromise between safety and efficacy.

Conclusion:

Recent studies provided some evidence that bumetanide can be a novel pharmacological agent in treating core symptoms of ASD. Future studies are required to confirm the efficacy of this medication in individuals with ASD.

Intestinal first-pass effect of bumetanide in rats

The intestinal first-pass effect of bumetanide was investigated after intravenous and intraportal infusion, and intragastric and intraduodenal instillation of the drug to rats. The AUC(0-->8 h) values of bumetanide after intragastric and intraduodenal instillation of the drug, 10 and 20 mg/kg, were significantly smaller than AUC values after intraportal administration, suggesting that the gastrointestinal first-pass effect of bumetanide was considerable in rats. However, the AUC(0-->8 h) values of bumetanide between intragastric and intraduodenal instillation were comparable, suggesting that the gastric first-pass effect of bumetanide was almost negligible in rats. The AUC(0-->8 h) values of bumetanide after intraduodenal instillation were significantly smaller than AUC values after intraportal infusion at 10 (89.8 vs 569 microg min per ml) and 20 (304 vs 1230 microg min per ml) mg/kg, indicating that the first-pass organ(s) of bumetanide was intestine. The F values were 15.8 and 24.7% after intraduodenal instillation of bumetanide, 10 and 20 mg/kg, respectively. Approximately 76.1 and 76.5% of intraduodenally instilled bumetanide disappeared (as a result of absorption and first-pass effect) after 10 and 20 mg/kg, respectively. Therefore, it could be concluded that approximately 60. 3 and 51.8% of the oral dose of bumetanide disappeared by intestinal first-pass effect at 10 and 20 mg/kg, respectively.

Pharmacokinetics and pharmacodynamics of bumetanide in critically ill pediatric patients

This prospective, open-label, clinical trial was conducted to describe the pharmacology of bumetanide in pediatric patients with edema. Nine infants, children, and young adults with edema who were selected for diuretic therapy were studied. After a brief baseline period, each patient received parenteral bumetanide 0.2 mg/kg divided into two equal doses and administered every 12 hours. Urine excretion rate, fractional and total excretion of Na+, Cl-, and K+, creatinine clearance, and plasma and urine concentrations of bumetanide were measured at multiple intervals after drug administration. Bumetanide caused significant increases in the excretion rate of urine and each measured electrolyte. Unexpectedly, creatinine clearance increased dramatically after each dose. Adverse effects, including hypokalemia and hypochloremic metabolic alkalosis, were evident by the end of the treatment period. The plasma pharmacokinetics of bumetanide revealed mean +/- standard deviation values for total clearance and apparent volume of distribution of 3.9 +/- 2.4 mL/min/kg and 0.74 +/- 0.54 L/kg, respectively. Patients excreted an average of 34% of each dose unchanged in the urine over 12 hours. Plasma concentrations of bumetanide accurately predicted several renal effects using a link model with similar pharmacodynamic parameters in each case. Parenteral bumetanide 0.1 mg/kg administered every 12 hours produced significant beneficial and adverse effects in these critically ill pediatric patients with edema. Pharmacokinetic parameters are similar to those previously reported for infants. Plasma concentrations of bumetanide can predict effect-compartment pharmacodynamics.

Quantitative structure-pharmacokinetic relationships for systemic drug distribution kinetics not confined to a congeneric series

Many attempts have been made to describe quantitative structure-pharmacokinetic relationships within a congeneric series of drug molecules. The goal is to develop a predictive relationship that could predict in vivo results for other drugs within that series. These studies typically evaluate pharmacokinetic parameters that are reflective of both distribution and elimination processes. This work utilizes the results from 17 noncongeneric drugs reported in 18 pharmacokinetic studies. The objective was to determine if drug distribution parameters that were independent of elimination could be predicted from easily measured physicochemical parameters with a data base that included a wide variety of drugs that were not congeners of one another. Regression models utilizing a linear and a quadratic response surface were used to predict the various distribution parameters from physicochemical parameters, including molecular weight, intrinsic solubility, alcohol solubility, protein binding, and the distribution coefficient. Analogous to the extent of absorption, the extent of drug distribution can be predicted reasonably well by the probability that the drug will distribute into the peripheral system before being eliminated and by the volume of distribution at steady state. The duration of distribution, analogous to the rate of absorption, can be predicted by the mean transit time through the peripheral system the mean residence time of the drug in the peripheral system and the intrinsic mean residence time in the peripheral system. The ability to use statistical models to approximate drug distribution parameters without the constraints of working within a congeneric series provides some valuable opportunities.

Pharmacokinetics and pharmacodynamics of bumetanide after intravenous and oral administration to rats: absorption from various GI segments

Bumetanide, 2, 8, and 20 mg/kg, was administered both intravenously and orally to determine the pharmacokinetics and pharmacodynamics of bumetanide in rats (n = 10-12). The absorption of bumetanide from various segments of GI tract and the reasons for the appearance of multiple peaks in plasma concentrations of bumetanide after oral administration were also investigated. After i.v. dose, the pharmacokinetic parameters of bumetanide, such as t1/2 (21.4, 53.8 vs. 127 min), CL (35.8, 19.1 vs. 13.4 ml/min per kg), CLNR (35.2, 17.8 vs. 12.6 ml/min per kg) and VSS (392, 250 vs. 274 ml/kg) were dose-dependent at the dose range studied. It may be due to the saturable metabolism of bumetanide in rats. After i.v. dose, 8-hr urine output per 100 g body weight increased significantly with increasing doses and it could be due to significantly increased amounts of bumetanide excreted in 8-hr urine with increasing doses. The total amount of sodium and chloride excreted in 8-hr urine per 100 g body weight also increased significantly after i.v. dose of 8 mg/kg, however, the corresponding values for potassium were dose-independent. After oral administration, the percentages of the dose excreted in 24-hr urine as unchanged bumetanide were dose-independent. Bumetanide was absorbed from all regions of GI tract studied and approximately 43.7, 50.0, and 38.4% of the orally administered dose were absorbed between 1 and 24 hr after oral doses of 2, 8, and 20 mg/kg, respectively. Therefore, the appearance of multiple peaks after oral administration could be mainly due to the gastric emptying patterns.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetics and pharmacodynamics of bumetanide after intravenous and oral administration to spontaneously hypertensive rats and DOCA-salt induced hypertensive rats

The pharmacokinetics and pharmacodynamics of bumetanide were investigated after intravenous (i.v.) administration, 10 mg kg-1, and oral administration, 20 mg kg-1, to spontaneously hypertensive rats (SHRs) and deoxycorticosterone acetate-salt induced hypertensive rats (DOCA-salt rats). After i.v. administration, the pharmacokinetic and pharmacodynamic parameters of bumetanide did not vary significantly between SHRs and the control Wistar rats. Similar results were also shown between DOCA-salt rats and the control Sprague-Dawley (SD) rats. After oral administration, the AUC0-12 h decreased significantly (186 versus 335 micrograms min ml-1) in SHRs and this resulted in decreased F(15.4 versus 23.6 and 2.78 versus 5.76% using two equations) in SHRs when compared with the control Wistar rats, although none of the other pharmacokinetic parameters varied significantly between SHRs and Wistar rats. This effect seemed to be due to the decreased enterohepatic recirculation of bumetanide in SHRs: the amounts of both bumetanide and its glucuronide product, which are capable of enterohepatic recirculation, excreted in 8 h bile juice decreased significantly in SHRs (11.3 versus 37.4 micrograms as expressed in terms of bumetanide) when compared with Wistar rats. The pharmacodynamic parameters did not vary significantly between SHRs and Wistar rats after oral administration of bumetanide. The pharmacokinetic and pharmacodynamic parameters of bumetanide did not vary significantly between DOCA-salt rats and SD rats after oral administration of the drug. The liver weights compared to body weight increased significantly in SHRs when compared with Wistar rats and the corresponding values for the kidney increased significantly in DOCA-salt rats when compared with SD rats.

Effect of intravenous infusion time on the pharmacokinetics and pharmacodynamics of the same total dose of bumetanide

The pharmacokinetics and pharmacodynamics of bumetanide were evaluated after intravenous (i.v.) administration of the same total dose of bumetanide in different lengths of infusion times, 10 s (treatment I), 1 h (treatment II), and 4 h (treatment III) to rabbits. The fluid loss in urine was immediately replaced volume for volume with i.v. infusion of lactated Ringer's solution. Some pharmacokinetic parameters of bumetanide were infusion time-dependent and it might be due to the saturable metabolism of bumetanide. For example, the mean values of CL (13.6, 25.3 vs 18.2 ml min-1 kg-1), MRT (9.70, 10.6 vs 21.8 min), Vss (128, 217 vs 378 ml kg-1), and CLNR (2.71, 9.24 vs 6.44 ml min-1 kg-1) increased when the same dose of bumetanide was infused in 1 h or 4 h. However, the mean values of t1/2, and CLR were not significantly different among three treatments. The diuretic effects (urine outputs and urinary excretions of sodium and chloride) increased significantly in 1 and 4 h of infusion although the total amounts of urinary excretion of unchanged bumetanide were 21.8 and 20.5 per cent lower in treatments II and III, respectively, when compared with the value in treatment I; the mean values of 8-h urine outputs were 373, 922, and 1030 ml for 10s, 1 h, and 4 h of infusion, respectively, and the corresponding values for 24-h sodium excretions were 49.0, 82.8, and 121 mmol, and for chloride were 47.5, 71.1, and 114 mmol. It could be due to the higher diuretic efficiencies in treatments II and III. Plasma concentrations of bumetanide, and hourly urine outputs and hourly urinary excretion rates of bumetanide, sodium, potassium, and chloride during the apparent steady state (between 1 and 4 h) in the 4 h infusion study were fairly constant.

Factors influencing the protein binding of bumetanide using an equilibrium dialysis technique

Factors that influence the plasma protein binding of bumetanide were evaluated using equilibrium dialysis. It took approximately 12 h of incubation to reach an equilibrium between plasma and isotonic phosphate buffer of pH 7.4 containing 3% dextran using a Spectrapor 2 membrane (mol. wt cut-off = 12,000-14,000) in a water-bath shaker kept at 37 degrees C and at a rate of 50 oscillations per min. Bumetanide was fairly stable in both 4% human serum albumin (HSA) and in the isotonic phosphate buffer of pH 7.4 for up to 24 h. The binding of bumetanide to 4% HSA was constant (87.5 +/- 1.73%) at bumetanide concentrations ranging from 0.1 to 100 micrograms/ml. The extents of binding were 72.0, 83.3, 88.5, 90.2, 91.3 and 91.4% at albumin concentrations of 0.5, 1, 2, 3, 4 and 5 g/100 ml, respectively, and increased with a decrease in incubation temperature; the values bound were 94.6, 90.3 and 89.3% when incubated at 4, 22 and 37 degrees C, respectively. The binding of bumetanide was independent of the buffer composition used, the quantities of AAG (up to 0.32%), heparin (up to 40 units/ml), sodium azide (up to 0.5%) and anticoagulants (EDTA, heparin and citrate). The free fraction of bumetanide in rabbit plasma (2.91%) was significantly higher than in humans (1.98%) or rats (1.85%).

Effects of phenobarbital and 3-methylcholanthrene pretreatment on the pharmacokinetics and the pharmacodynamics of bumetanide in rats

The effects of pretreatment with the enzyme inducers, phenobarbital (PB) and 3-methylcholanthrene (3-MC), on the pharmacokinetic and pharmacodynamic parameters of bumetanide were examined in rats. The nonrenal clearance (19.3 vs 29.6 ml min-1 per kg) of bumetanide increased significantly in PB treated rats. This suggested that the nonrenal metabolism of bumetanide is increased by pretreatment with PB, which was supported by significantly increased amounts of bumetanide glucuronide and desbutyl bumetanide excreted in 8-h urine, and reduced amounts of bumetanide remaining per gram of tissue after 30-min incubation of 100 micrograms of bumetanide with the 9000 xg supernatant fraction of liver, stomach, and kidney tissue homogenates in PB treated rats. The contents of hepatic cytochrome P-450 (1.29 vs 2.15 nmol mg-1 protein) and the weights of liver and stomach increased significantly in PB treated rats, suggesting that the metabolizing enzymes for bumetanide are induced by pretreatment with PB. The 8-h urine output per 100 g body weight was not significantly different by pretreatment with PB although the amounts of bumetanide excreted in 8-h urine increased significantly in PB treated rats. It could be explained by the fact that the dose of bumetanide used results in urinary concentrations at the plateau of the concentration-effect relationship. Therefore, the alteration in the urinary excretion rate of bumetanide by pretreatment with PB would not alter the diuretic effect. In 3-MC treated rats, pharmacokinetic and pharmacodynamic parameters were not significantly different and it suggested that the metabolizing enzymes for bumetanide are not induced by pretreatment with 3-MC although the contents of hepatic cytochrome P-450 and the weights of liver and stomach increased significantly by pretreatment with 3-MC.

Metabolism of the diuretic bumetanide in healthy subjects and patients with renal impairment

The pharmacokinetics and metabolism of orally administered bumetanide were studied in five healthy subjects and in five patients with renal insufficiency. Healthy subjects excreted 51% of the dose as unchanged drug in the urine, whilst the patients with renal insufficiency excreted only 11% of the dose as bumetanide. Similarly the urinary excretion of the gamma-hydroxybutyl metabolite was reduced from 6% in healthy subjects to 2.3% in patients with renal impairment. In both groups of subjects the mean elimination half-life of the metabolite was greater than for bumetanide. The results indicate a possible accumulation of bumetanide and metabolite in patient with renal failure.

Clinical pharmacokinetics in heart failure. An updated review

Pharmacokinetics is the study of the effect that the body has on drug absorption, distribution, metabolism and excretion. The pharmacokinetics of a specific drug are assessed by the volume of distribution, bioavailability, clearance and elimination half-life. Elimination half-life is directly related to the volume of distribution and inversely related to clearance. Any 1 or more of these parameters may be altered by physiological changes such as ageing, or disease states such as congestive heart failure. Congestive heart failure is associated with hypoperfusion to various organs including the sites of drug clearance, i.e. the liver and kidneys. It also leads to organ congestion as seen in the liver and gut. The main changes in drug pharmacokinetics seen in congestive heart failure are a reduction in the volume of distribution and impairment of clearance. The change in elimination half-life consequently depends on whether both clearance and the apparent volume of distribution change, and the extent of that change. Pharmacokinetic changes are not always predictable in congestive heart failure, but it seems that the net effect of reduction in the volume of distribution and impairment of clearance is that plasma concentrations of drugs are usually higher in patients with congestive heart failure than in healthy subjects. The changes in pharmacokinetics assume importance only in the case of drugs with a narrow therapeutic ratio (e.g. digoxin) and some of the antiarrhythmics such as lignocaine (lidocaine), procainamide and disopyramide. This necessitates reduction in both the loading and maintenance doses. Prolongation of the elimination half-life leads to delay in reaching steady-state, and therefore dose increments must be made more gradually. Plasma concentration measurements of the drugs concerned are a good guide to therapy and help to avoid toxicity. Pharmacokinetic changes are of less importance in the case of drugs with immediate clinical response, e.g. diuretics and intravenous vasodilators such as nitrates and phosphodiesterase inhibitors. The dose in the latter group can be titrated to the desired effect. Not all adverse reactions to drugs that may occur in heart failure are the result of alterations in pharmacokinetics; rather, some may be due to important drug interactions. An interaction may occur directly e.g. reduction of renal clearance of digoxin by captopril and quinidine; or indirectly, e.g. through diuretic-induced hypokalaemia, which exacerbate arrhythmias associated with digoxin and antiarrhythmics such as quinidine and procainamide.

Comparison of loop diuretics in patients with chronic renal insufficiency

Furosemide and bumetanide share a number of characteristics including reduced natriuretic effects in azotemic patients. It has been presumed that this condition affects each drug equally. Previous studies, however, suggest dissimilar pathways of delivery to their sites of action. Though not rigorously tested, this potential disparity might cause them to differ when used in azotemia. We, therefore, assessed the pharmacokinetic and pharmacodynamic characteristics of intravenously administered furosemide and bumetanide in ten adult patients with stable, chronic renal insufficiency (mean creatinine clearance = 14.1 +/- 2.0 ml/min/1.73 m2) in a randomized, cross-over study during controlled sodium intake. Our goals were to assess differences in diuretic effectiveness and in so doing to determine the dose required to produce a maximal response. The mean diuretic doses of 172 and 4.3 mg for furosemide and bumetanide, respectively (ratio = 40:1) were sufficient to produce a maximum response. Despite similarities in maximal fractional excretion of sodium (18.2 +/- 2.6% with furosemide vs. 19.4 +/- 4.5% with bumetanide, P = 0.687) demonstrating an equal tubular responsiveness to both drugs, overall response as quantified by cumulative natriuresis in the initial eight hour period was 52% greater with furosemide (108 +/- 17 vs. 71 +/- 7 mEq; P = 0.042). The difference in total excreted sodium was accounted for by a preserved nonrenal clearance of bumetanide (113 +/- 12 compared to 53 +/- 5 ml/min for furosemide, P = 0.001) which resulted in relatively less bumetanide in serum available to be delivered into the urine.(ABSTRACT TRUNCATED AT 250 WORDS)

Theorems and implications of a model-independent elimination/distribution function decomposition of linear and some nonlinear drug dispositions. III. Peripheral bioavailability and distribution time concepts applied to the evaluation of distribution kinetics

Disposition decomposition analysis (DDA) is applied to evaluate the rate and extent of drug delivery from the sampling compartment to the peripheral system, i.e., peripheral bioavailability. Four parameters are introduced which are useful in quantifying peripheral bioavailability. The compounded peripheral bioavailability, F comp, is the ratio between the total compounded amount of drug transferred to the peripheral system and the injected dose, D. The AUC peripheral bioavailability, FAUC, is the ratio between the area under the amount vs. time curves for the peripheral system and the sampling compartment. The distribution time td, is the time following an i.v. bolus at which the net transfer of drug to the peripheral system reverses in direction. The maximum peripheral bioavailability, Fmax, is the maximum fraction of an i.v. bolus dose that is present in the peripheral system at any one time. Equations are derived which permit estimation of those parameters from drug concentrations in the sampling compartment. Simple algorithms and a computer program are provided for estimating Fcomp, FAUC, td, Fmax, and other parameters relevant to DDA for drugs that exhibit a linear polyexponential bolus response. Estimates of Ecomp, FAUC, td, and Fmax are presented for several drugs.

Single pass mean residence time in peripheral tissues: a distribution parameter intrinsic to the tissue affinity of a drug

The single pass mean residence time in peripheral tissues, tp1, is a characteristic constant of linear pharmacokinetic systems and nonlinear systems with linear distribution kinetics. It is descriptive of distribution kinetics in such systems and is not dependent on elimination kinetics as are other related parameters, e.g., mean residence time in peripheral tissues, tp. Equations are derived which permit estimation of tp1 from experimental data for systems in which no peripheral elimination occurs. The type of data required are systemic drug levels resulting from iv administration. The probability density function for single pass residence time in peripheral tissues is derived. It is shown that tp1 is related to the amount of drug in the peripheral tissues at steady state according to (Ap)ss = CLdCsstp1, where CLd is the distribution clearance, and Css is the steady-state systemic drug level. Values of tp1 are presented for several drugs.

Pharmacokinetics and diuretic effect of bumetanide following intravenous and intramuscular administration to horses

Concentrations of the potent diuretic bumetanide were determined by a sensitive high performance liquid chromatographic procedure in plasma and urine from horses following intravenous and intramuscular administration of a dose rate of 15 micrograms/kg. The elimination half-life was found to be 6.3 min, the volume of distribution at steady state 68 ml/kg and the total plasma clearance 10.9 ml/min/kg. The onset of diuresis occurred within 15 min and diuresis was no longer apparent 1 h after i.v. administration. Given by the intramuscular (i.m.) route, bumetanide was rapidly absorbed; bioavailability was 70-80%. i.m. administration of bumetanide prolonged its plasma half-life (11-27 min) and enhanced and prolonged its diuretic effect.

Disposition and response to bumetanide and furosemide

Bumetanide and furosemide are potent loop diuretics; the former is 40 to 50 times more potent than the latter on a weight basis. Bumetanide is absorbed more quickly than furosemide and is twice as bioavailable. Both drugs exhibit changes in elimination in the presence of renal insufficiency as well as changes in the time course of absorption in congestive heart failure. More data are needed to assess potential differences between them in various clinical conditions.

Theorems and implications of a model-independent elimination/distribution function decomposition of linear and some nonlinear drug dispositions. II. Clearance concepts applied to the evaluation of distribution kinetics

The disposition decomposition approach is employed to derive clearance parameters descriptive of drug distribution kinetics. The name distribution clearance, CLd, is given to a characteristic constant of linear and some nonlinear pharmacokinetic systems. CLd is the clearance associated with the steady-state rate of drug transfer from the peripheral tissues to the systemic circulation. Also introduced is the elimination clearance, CLe, which is associated with the total drug transfer rate from the systemic circulation in linear systems. Estimates of CLd and CLe are presented for several drugs.

Bumetanide. A review of its pharmacodynamic and pharmacokinetic properties and therapeutic use

Bumetanide is a potent 'loop' diuretic for the treatment of oedema associated with congestive heart failure, hepatic and renal diseases, acute pulmonary congestion and premenstrual syndrome and in forced diuresis during and after surgery. Bumetanide may be given orally, intravenously or intramuscularly and produces a rapid and marked diuresis, and increased urinary excretion of sodium, chloride and other electrolytes (within 30 minutes) which persists for 3 to 6 hours. Its principal site of action is on the ascending limb of the loop of Henle, with a secondary action on the proximal tubule. Pharmacologically, bumetanide is about 40-fold more potent than frusemide (furosemide), with the exception of its effects on urinary potassium excretion where its potency is lower. Studies in patients with oedema due to congestive heart failure, pulmonary oedema or hepatic disease show that oral or intravenous bumetanide 0.5 to 2 mg/day produces results comparable to those with frusemide 20 to 80 mg/day. In acute pulmonary oedema, intravenous bumetanide produces a very rapid diuresis. Higher doses of bumetanide may be required (up to 15 mg/day) in patients with chronic renal failure or nephrotic syndrome. In these patients muscle cramps are not uncommon with bumetanide, but glomerular filtration rates are unaffected. In most studies, diuretic effects were accompanied by decreased bodyweight, abdominal girth and improvements in a variety of haemodynamic parameters. Comparison of bumetanide with frusemide at a dose ratio of 1 : 40 reveals no significant differences in clinical response with the exception of renal disease, where patients with oedema appear to respond better to bumetanide. Combination with thiazide diuretics enhances the clinical response to bumetanide. Potassium supplements and spironolactone may be beneficial additions to bumetanide where patients at risk of hypokalaemia can be identified. Clinically important side effects are infrequent, with audiological impairment occurring to a lesser extent than with frusemide. Bumetanide thus offers an important alternative to frusemide when a 'loop' diuretic is indicated.

Pharmacokinetics of bumetanide following intravenous, intramuscular, and oral administrations to normal subjects

The pharmacokinetics of bumetanide was studied in 12 normal subjects after 1-mg intravenous, intramuscular, oral solution, and tablet administrations in a random four-treatment crossover design. Plasma and urine concentrations of intact bumetanide were analyzed by a sensitive and specific RIA. The pharmacokinetics of bumetanide after intravenous administration was characterized by a biexponential equation, including an initial disposition phase (t 1/2, alpha = 5.1 min), followed by a slower elimination phase (t 1/2, beta = 44 min). Bumetanide pharmacokinetics after intramuscular and oral administration could be described by a biexponential equation with first-order absorption and elimination. Bumetanide is rapidly absorbed via the intramuscular and oral routes, with mean +/- SD maximum plasma concentrations of 38.2 +/- 9.8 (intramuscular), 34.0 +/- 10.6 (oral solution), and 30.9 +/- 14.6 ng/mL (tablet) achieved within 0.34 +/- 0.23, 0.76 +/- 0.27, and 1.8 +/- 1.2 h after dosing, respectively. The drug is rapidly eliminated from the body after intravenous, intramuscular, oral solution, and oral tablet administrations, with half-lives ranging from 24-86, 47-139, 27-71, and 26-99 min, respectively. Approximately 70% of a parenteral dose and 60% of an oral dose are excreted as intact drug in urine taken 0-24 h after administration. The extent of bioavailability of bumetanide from the tablet and oral solution dosage forms are equivalent, and the absolute bioavailability of the intramuscular and oral preparations are approximately 100 and 80%, respectively. This is consistent with the predicted limited extent of first-pass metabolism after complete absorption of an oral dose.(ABSTRACT TRUNCATED AT 250 WORDS)

Bumetanide and furosemide in heart failure

We assessed the handling of and response to oral bumetanide (1.0 and 2.0 mg) and to furosemide (40 and 80 mg) in 20 patients with stable, compensated congestive heart failure (CHF), comparing the two drugs and, in addition, examining differences from normal subjects. Bumetanide and furosemide were similar in time course of absorption, but patients with CHF had considerably prolonged absorption compared to normal subjects causing attainment of lower peak concentrations of drug. In both CHF and normal subjects, more bumetanide than furosemide was absorbed. The elimination half-life of furosemide was approximately twice that of bumetanide, and both were about two times longer than respective values in normal subjects. "Dose"-response curves were shifted downward from normal with both drugs. In patients with CHF, overall response did not differ between bumetanide and furosemide. The two drugs exhibit subtle differences, the clinical importance of which appears to be negligible from this study. Importantly, however, both drugs showed delayed absorption causing attainment of peak urinary excretion rates of diuretic two- to threefold lower than in normal subjects. This effect along with the abnormal responsivity of the tubule may contribute to the "resistance" to oral doses of diuretics observed clinically even though no quantitative malabsorption of drug occurs.

Bumetanide: a new loop diuretic (Bumex, Roche Laboratories)

Bumetanide is a recently introduced diuretic that inhibits sodium transport in the thick ascending limb of the loop of Henle. It is structurally and pharmacologically similar to furosemide, but is approximately 40 times as potent on a milligram-for-milligram basis. After oral administration, it is rapidly absorbed, with peak serum concentrations attained at approximately 30 minutes. Its pharmacokinetic parameters are similar to those of furosemide. Bumetanide has demonstrated efficacy in the management of edema associated with congestive heart failure, hepatic cirrhosis, and renal insufficiency. Bumetanide has demonstrated an adverse-reaction profile similar to that of furosemide, although the incidence of hypochloremia and hypokalemia is greater with bumetanide. The incidence of hyperglycemia and ototoxicity is greater with furosemide. The principal indication for bumetanide may be in patients with increased risk of ototoxicity. Cost considerations should relegate bumetanide to a secondary role for the treatment of sodium and fluid retention in most clinical settings.

The pharmacokinetics and pharmacodynamics of the diuretic bumetanide in hepatic and renal disease

1 Bumetanide (1 mg) was given orally and intravenously to a group of patients with chronic renal failure (n = 6) and to another group with cirrhosis of the liver (n = 8). 2 The pharmacokinetics, using a two-compartment model, and the pharmacodynamics of the drug in these patients were compared with those previously obtained for normal subjects. 3 In the renal group serum bumetanide concentrations were higher than for the normal subjects and the terminal half-lives were significantly prolonged (P less than 0.001). A decreased whole body clearance was attributable to a low renal clearance of drug, the non-renal clearance being significantly increased (P less than 0.01). 4 For the patients with liver disease, serum bumetanide concentrations were higher than for the renal group, and the terminal half-lives were significantly further prolonged (P less than 0.001). Both non-renal and renal clearances were significantly reduced (P less than 0.001). 5 Absorption rates were not significantly altered in either group and the values of F (bioavailability) were 0.82 and 0.95 for the patients with renal disease and hepatic disease, respectively. 6 A poor pharmacodynamic response and a reduced bumetanide excretion rate were observed for the patients with chronic renal failure, whereas with hepatic disease normal bumetanide excretion rates were observed with an impaired diuretic response.

The pharmacokinetics and pharmacodynamics of bumetanide in normal subjects

The pharmacokinetics and pharmacodynamics of bumetanide (1 mg) administered either orally or intravenously were studied in a group of normal subjects using high-pressure liquid chromatography. A two-compartment model adequately fitted the intravenous data. Renal clearance (85 ml min-1) contributed 65% to the total elimination of bumetanide irrespective of whether a model-dependent or model-independent method was used. Oral administration of bumetanide elicited a greater and a more prolonged pharmacological response than did intravenous bumetanide. An attempt is made to relate the pharmacokinetics of the drug to its pharmacodynamics.

Pharmacology, therapeutic efficacy, and adverse effects of bumetanide, a new "loop" diuretic

Bumetanide is a recently developed natriuretic and diuretic agent, belonging to the "loop" class of diuretics. Since it is rapidly and almost completely absorbed after oral administration, oral and parenteral formulations have a similar pharmacokinetic profile. Peak plasma levels are achieved approximately 30 min after oral administration. The apparent half-life is 1.2-1.5 hr, and the volume of distribution is about 25 liters. Plasma clearance is 228-255 ml/min. Bumetanide is promptly and almost completely eliminated by metabolism of the butyl side chain and urinary excretion of the parent drug and its metabolites. The principle renal site of action is the ascending limb of the loop of Henle, with a minor effect on the proximal tubule. The drug causes decreases in both free water clearance (during water diuresis) and solute free water reabsorption (during hydropenia), increased fractional delivery of sodium chloride to the distal tubule and a natriuresis approaching 20% of the filtered load of sodium, calciuria, phosphaturia, and minimal bicarbonaturia. Extensive clinical studies have been conducted with both oral and parenteral bumetanide in patients with a variety of edematous conditions. The agent has been clearly demonstrated to be an effective diuretic in the treatment of edema due to cardiac disease (congestive heart failure) and edema, with or without ascites, due to hepatic disease. Bumetanide has also been shown effective in treating edema due to renal disease, even when modest to severe renal insufficiency is present, and it may be useful in the treatment of edema refractory to other loop diuretics. As would be predicted for any potent diuretic, bumetanide administration has been associated with hypokalemia, hypochloremia, metabolic aklalosis, hyperuricemia, and prerenal azotemia. Alterations in glucose metabolism are an inconsistent finding. Transient thrombocytopenia and granulocytopenia have been noted, but no consistent or important alterations in biochemical parameters have been observed. In some patients, especially those with renal failure receiving high doses, myalgias and muscle tenderness have been described. To date only a very limited potential for ototoxicity has been observed. Bumetanide has been administered without difficulty to patients having side effects from other loop diuretics.

High-performance liquid chromatographic assay for bumetanide in plasma and urine

A new high-performance liquid chromatographic (HPLC) method was developed for the analysis of bumetanide in plasma and urine. A reversed-phase column was fitted to the instrument and fluorescent (excitation lambda = 338 nm, emission lambda = 433 nm) and UV (254 nm) detectors were utilized to monitor simultaneously bumetanide and the internal standard, acetophenone, respectively. The assay is rapid, sensitive, and specific. Plasma bumetanide concentrations can be detected as low as 5 ng/ml using a 0.20-ml sample. Time-consuming extraction and/or derivatization steps are not required. The only clean-up procedure involved is the precipitation of plasma proteins with acetonitrile.