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)     

Pharmacodynamics and pharmacokinetics of omapatrilat in heart failure.

The purpose of this study was to determine the pharmacodynamics and pharmacokinetics of omapatrilat, administered orally (25 mg) or intravenously (10 mg) in 19 New York Heart Association class II and class III congestive heart failure (CHF) patients versus 17 healthy controls matched for age, race, gender, and weight. The plasma concentrations of atrial natriuretic peptide (ANP) increased by approximately 20% and 30% in CHF and control subjects, respectively, at 4 hours after intravenous or oral omapatrilat administration. Similar elevation in the cyclic guanosine monophosphate concentration (25% to 35%) and ANP urinary excretion (21 ng/24 h to 22 ng/24 h) was seen in all treatment groups after omapatrilat administration. Angiotensin-converting enzyme activity was > 90% inhibited at 4 hours after dosing and remained approximately 60% to 70% inhibited at 24 hours after dosing. The levels of endothelin-1 and endothelin-2 remained unchanged after oral or intravenous administration of omapatrilat. The maximal reduction in seated blood pressure compared with baseline was similarfor CHF and control subjects. Clinical pharmacokinetic parameters were similar in both groups after intravenous dosing, but maximum concentration and area under the concentration-time curve were elevated in CHF patients compared with controls after oral dosing. Omapatrilat was well tolerated; differences in systemic exposure and metabolism between CHF patients and controls did not appear to be clinically significant.     

Pharmacokinetics and bioavailability of dilevalol in normotensive volunteers

The bioavailability and pharmacokinetics of dilevalol following oral and intravenous administration were investigated in 12 healthy male volunteers. Dilevalol HCl was administered as a 200-mg oral tablet and a 50-mg intravenous infusion using a randomized cross-over design. Blood and urine samples were collected over 60 hours and analyzed for unchanged and total (unchanged plus Glusulase-released) dilevalol using a high performance liquid chromatography (HPLC) assay. After intravenous administration, total body clearance and volume of distribution of unchanged dilevalol were determined to be 23.2 mL/min/kg and 24.6 L/kg, respectively. After oral administration, a mean maximum concentration of 62 ng/mL was reached at an average peak time of 1.4 hours. Drug was eliminated with a half-life of 8.3 hours after oral administration and 12 hours after intravenous administration. Based on plasma levels and urinary excretion of total dilevalol, the drug was completely absorbed; however, due to first-pass metabolism, the absolute bioavailability of unchanged drug was 11 to 14%.     

The pharmacokinetics of oxybutynin in man

Summary We have studied the pharmacokinetics of oxybutynin (Ditropan) after single oral (5 mg) and intravenous administration (1 and 5 mg), and after repeated oral administration in healthy volunteers.Oxybutynin was rapidly absorbed, maximum plasma concentrations (8 ng·ml^–1) being reached in less than 1 h. The absolute systemic availability averaged 6% and the tablet and solution forms displayed similar relative systemic availability.Plasma concentrations of oxybutynin fell biexponentially, the elimination half-life being about 2 h. There was a large interindividual variation in oxybutynin plasma concentrations. Almost no intact drug could be recovered in the urine. During repeated oral administration steady-state was reached after eight days of treatment.The low absolute systemic availability of oxybutynin, the large interindividual variability in its plasma concentrations, and the apparent absence of intact oxybutynin in the urine suggest that its major pathway of elimination is hepatic metabolism.     

Disposition and pharmacokinetics of temozolomide in rat

1. Temozolomide, an imidazotetrazine derivative, is a cytotoxic alkylating agent of broad-spectrum antitumour activity. The absorption, metabolism, distribution and excretion of temozolomide have been investigated in male and female Sprague-Dawley and Long-Evans rats following single oral or intravenous dose administration of 200 mg m(-2) non-radiolabelled or (14)C-radiolabelled temozolomide. The distribution of (14)C-temozolomide was also evaluated by whole-body autoradiography in male Sprague-Dawley rats. Plasma concentrations of temozolomide and its active metabolite 3-methyl-(triazen-1-yl)imidazole-4-carboxamide (MTIC) were determined by high-performance liquid chromatography (HPLC) with ultraviolet detection. Plasma, urine and faeces were profiled by HPLC with radiochemical detection. 2. Temozolomide was rapidly and extensively (>90%) absorbed and widely distributed in tissues. The distribution pattern of radioactivity was gender independent. Penetration into the brain following oral or intravenous administration was 35-39% based on the brain/plasma AUC ratio. 3. Following intravenous or oral administration, temozolomide was primarily eliminated renally (75-85% of the dose) as either unchanged drug, a carboxylic acid analogue, AIC (a degradation product) and a highly polar unidentified peak. Biliary excretion was minimal (1.4-1.6%). The pharmacokinetics (oral versus intravenous) were similar and gender independent. The absolute oral availability was 96-100%. Temozolomide was rapidly eliminated (t(1/2) = 1.2 h) and converted to MTIC. 4. Systemic exposure to MTIC was about 2% that of temozolomide. Overall, the disposition of temozolomide in rats was similar to that observed in humans.     

Bioavailability and kinetics of cibenzoline in patients with normal and impaired renal function

To test the hypothesis that renal failure alters the disposition of cibenzoline in humans, an absolute bioavailability and elimination kinetic study was performed. We used the simultaneous administration of a stable isotope variant (SASIV). Eight healthy volunteers and eight matched hemodialysis patients each received simultaneously an 80-mg intravenous infusion of 15N-2-cibenzoline and a single 80-mg cibenzoline capsule. Cibenzoline plasma concentrations were assayed by a gas chromatographic-mass spectrometric assay. A compartment-independent kinetic analysis showed a plasma clearance of 707 mL/min and an elimination half-life of 7.3 hours after the intravenous dose in healthy volunteers. In renal-failure patients, cibenzoline clearance decreased to 224 mL/min and half-life increased to 22.4 hours. Decreased plasma clearance was due to decreases in both renal and nonrenal clearance. Absolute bioavailability was 83% and 90% in healthy volunteers and renal-failure patients, respectively. Hemodialysis accounted for only 13% of drug clearance.     

Absolute oral bioavailability of traxoprodil in cytochrome P450 2D6 extensive and poor metabolisers

BACKGROUND: Traxoprodil, a substituted 4-phenylpiperidine, is an N-methyl-D-aspartate (NMDA) receptor antagonist that is selective for receptors containing the NR2B subunit. In vivo and in vitro studies examining the disposition of traxoprodil have demonstrated that it is mainly metabolised by cytochrome P450 (CYP) 2D6, a major drug-metabolising enzyme that exhibits a genetic polymorphism. OBJECTIVE: To assess the single-dose absolute oral bioavailability of traxoprodil in healthy male volunteers phenotyped as either CYP2D6 extensive or poor metabolisers. METHODS: This was an open-label, three-way crossover study. Traxoprodil was administered as a single dose orally in solution of 50, 100 and 300mg and intravenously as a constant rate 2-hour infusion of 50 and 100mg. CYP2D6 phenotype was assigned following single-dose dextromethorphan administration. RESULTS: In poor metabolisers (n = 6), oral bioavailability was approximately 80% and was consistent with a liver extraction ratio of approximately 20% (plasma clearance of approximately 4 mL/min/kg) indicating near complete absorption. Following intravenous administration, the mean volume of distribution at steady state (V(ss)) was moderate (approximately 6.5 L/kg) and the mean elimination half-life (t((1/2))) was approximately 20 hours. Following oral administration the mean maximum plasma concentration (C(max)) and area under the plasma concentration-time curve from time zero to infinity (AUC(infinity)) increased approximately proportionally with dose. In extensive metabolisers (n = 11), oral bioavailability was dose-dependent and nonlinear. At the 100mg dose, the absolute oral bioavailability was approximately 39.5%. Overall, the oral bioavailability ranged from 22.8% to 62.1% and its estimation was confounded by large differences in plasma concentrations at oral doses without equivalent intravenous doses. Following intravenous administration, plasma clearance was high (approximately 27 mL/min/kg), the V(ss) was moderate (approximately 4 L/Kg) and the t((1/2)) was approximately 2-4 hours. Following oral administration the C(max) and AUC(infinity) increased more than proportionally with dose. Apparent oral clearance decreased with increasing oral dose. However, t((1/2)) was approximately the same at all doses (approximately 4 hours). CONCLUSION: The pharmacokinetics of traxoprodil were quite different in the two phenotypes. In extensive metabolisers, the oral bioavailability was nonlinear and dose-dependent, while in poor metabolisers, oral bioavailability appeared to be linear and dose-independent. Based on the pharmacokinetics in extensive and poor metabolisers, the nonlinear oral bioavailability in extensive metabolisers may be attributed to saturation of hepatic first-pass CYP2D6 metabolism. Thus, at a high oral dose, the impact of CYP2D6 metabolism on traxoprodil pharmacokinetics is minimal.     

Comparative biotransformation of radiolabeled [(14)C]omapatrilat and stable-labeled [(13)C(2)]omapatrilat after oral administration to rats, dogs, and humans.

Omapatrilat, a novel vasopeptidase inhibitor, is under development for the treatment of hypertension and congestive heart failure. This study describes the comparative biotransformation of radiolabeled [(14)C]- and stable-labeled [(13)C(2)]omapatrilat after administration of single oral doses to rats, dogs, and humans. The metabolites were identified by a combination of methods including reduction, hydrolysis, and comparison of high performance liquid chromatography retention times with those of the synthetic standards. Urinary metabolites were further characterized by liquid chromatography tandem mass spectrometry analysis. Prominent metabolites identified in human plasma, which were also present in rat and dog plasma, were S-methyl omapatrilat and S-2-thiomethyl-3-phenylpropionic acid. Omapatrilat accounted for only a small portion of the extractable radioactivity in plasma in all three species. A portion of the plasma radioactivity was unextractable in all three species (27-53%). The majority of unextractable radioactivity in plasma was characterized after dithiothreitol reduction to be omapatrilat and (S)-2-thio-3-phenylpropionic acid, both apparently bound to plasma proteins by reversible disulfide bonds. The major human urinary metabolites were the amine hydrolysis product, diasteromeric sulfoxide of (S)-2-thiomethyl-3-phenylpropionic acid, acyl glucuronide of S-methyl omapatrilat, and S-methyl omapatrilat. The minor metabolites were acyl glucuronide of (S)-2-thiomethyl-3-phenylpropionic acid, L-cysteine mixed disulfide of omapatrilat, diastereomers of S-methyl sulfoxide of omapatrilat, and S-methyl omapatrilat ring sulfoxide. The metabolic profiles of dog and human urine were qualitatively similar whereas rat urine showed only metabolites arising from hydrolysis of omapatrilat. Unchanged omapatrilat was not found in rat, dog, or human urine samples indicating extensive metabolism in vivo.     

Pharmacokinetics and concentration--effect relationships of bevantolol (CI-775) in normal volunteers

The pharmacokinetic handling of the beta 1 selective adrenoceptor blocking drug, bevantolol, was studied in 12 healthy volunteers. After intravenous (i.v.) administration of 50 mg of the drug, there was a biexponential decline in plasma levels with a terminal elimination half life (t1/2) of 1.9 h (range 1.4-2.3 h) and a total apparent volume of distribution at equilibrium of 62 L. After oral administration of the same dose, the bioavailability averaged 57% (range 26-98%) and peak plasma levels varied over a threefold range. On average, less than 1% of the dose was eliminated unchanged in the urine, indicating that the clearance of the drug was accounted for almost entirely by metabolism. Plasma levels after oral dosing with food showed an average 75-min delay in achievement of peak plasma levels and an average 14% increase in the extent of bioavailability of the drug. A positive correlation (r = 0.79) existed between the logarithm of the plasma bevantolol level and the percentage of reduction in postexercise heart rate. A plasma drug level of approximately 200 ng/ml produced a 10% reduction in postexercise heart rate. Pharmacological studies using guinea pig atrial and tracheal tissue demonstrated that the beta-blocking potency and beta-selectivity of bevantolol were intermediate between those of metoprolol and atenolol.     

Pharmacokinetics of sulphadimethoxine in channel catfish (Ictalurus punctatus)

1. Plasma clearance, bioavailability, tissue disposition and elimination of 14C-sulphadimethoxine (SDM) were studied in channel catfish (Ictalurus punctatus) after intravenous (i.v.) and oral dosing (per os; p.o.) at 40 mg/kg body weight. 2. Analysis of blood SDM concentrations over time for intravascularly administered SDM showed that disposition and elimination were best described by a two-compartment pharmacokinetic model; estimated half-lives for SDM in blood were 0.09 and 12.6 h for the distribution and elimination phases, respectively. 3. SDM was found primarily in muscle tissue immediately after oral administration; however, clearance from muscle was rapid, with a half-life of 13.1 h. 4. With time, SDM-derived radioactivity became concentrated in the bile and was eliminated slowly (t 1/2 = 115.5 h). 5. Binding of SDM in channel catfish plasma was low (18%) and was non-specific and dose-independent. 6. With the exception of the initial, rapid clearance of SDM from blood, the pharmacokinetic parameters describing SDM distribution and elimination in channel catfish were similar to values reported for other vertebrate species; the rapid distribution of SDM from blood to the tissues in the catfish may be related to species differences in the plasma binding of SDM.     

Pharmacokinetics of eltoprazine in healthy subjects

The pharmacokinetics of eltoprazine in healthy male subjects was investigated after intravenous and oral dosing in one study, and after oral dosing of 14C-eltoprazine in a second study. It was shown that the absorption of eltoprazine from the gastro-intestinal tract was complete, and that absolute bioavailability was 100%. The mean elimination half-life of eltoprazine in plasma was about 8 hours. Approximately 40% of the dose was excreted unchanged in urine.     

The disposition and pharmacokinetics of ketoconazole in the rat

The disposition, biliary excretion, and pharmacokinetics of ketoconazole in Sprague-Dawley rats were determined after intravenous administration. Greater than 80% of the radioactivity after a 5 mg/kg iv dose of 3H-ketoconazole was excreted in the feces. Urinary excretion was essentially complete after 48 hr; however, fecal excretion was prolonged over a 7-day period. Biliary excretion of radioactivity averaged 54.3 +/- 18.0% of the dose over a 7.5-8-hr period in pentobarbital-anesthesized rats. The possibility of enterohepatic recirculation was examined using a linked rat technique. Less than 2% of the radioactivity was found in the recipient bile over 9-12 hr. In eight male rats, the plasma pharmacokinetics of ketoconazole, as determined by an HPLC assay with fluorescence detection, were as follows: VD = 655 +/- 91 ml/kg, Cl = 14.4 +/- 5.1 ml/min/kg, and t 1/2 = 35.0 +/- 12.3 min. Three of the rats were given an additional oral dose to determine absolute bioavailability. The time to peak was 30-60 min, and the bioavailability was 35.8 +/- 3.55%. Previous studies have indicated that ketoconazole is well absorbed in rats; therefore, the poor bioavailability is probably due to first pass metabolism. The prolonged fecal excretion of radioactivity from an intravenous dose was probably caused by slow elimination of ketoconazole metabolites.     

Disposition of pravastatin sodium, a tissue-selective HMG-CoA reductase inhibitor, in healthy subjects.

Pravastatin sodium, a competitive inhibitor of HMG-CoA reductase, is a new orally effective hypocholesterolaemic agent. In a two-way crossover study, eight healthy male subjects each received an intravenous and an oral dose of [14C]-pravastatin sodium. The oral absorption of [14C] activity from pravastatin sodium was about 34% and the oral bioavailability was about 18%, suggesting first-pass metabolism of pravastatin. After the intravenous dose, the recovery of radioactivity averaged 60% and 34% in urine and faeces, respectively. Corresponding values were 20% (urine) and 71% (faeces) for the oral dose. The estimated average plasma elimination half-life of pravastatin was 0.8 and 1.8 h for the intravenous and oral routes, respectively. The average values for total and renal clearances were 13.5 and 6.3 ml min-1 kg-1, respectively, and the steady-state volume of distribution averaged 0.51 kg-1. These results suggest that both kidney and liver are important sites of elimination for pravastatin.     

Absolute bioavailability,pharmacokinetics, and urinary excretion of the novel antimigraine agent almotriptan in healthy male volunteers

Absolute bioavailability, pharmacokinetics, and urinary excretion of almotriptan, a novel 5-HT(1B/1D) receptor agonist, were studied in 18 healthy males following single intravenous (i.v.) (3 mg), subcutaneous (s.c.) (6 mg), and oral (25 mg) doses. Volunteers received each dose in a randomized sequence separated by a 7-day washout. Blood and urine samples for pharmacokinetic evaluations were taken for up to 24 hours after dosing. The disposition kinetics of almotriptan after i.v. and s.c. administration showed biphasic decline described by a two-compartment model. The fastest disposition phase was well observed, although estimates of the rate constant showed high variability. After s.c. administration of almotriptan, the bioavailability was 100% with a time to maximum plasma concentration (tmax) of 5 to 15 minutes, whereas after oral administration, the bioavailability was about 70% with a tmax of 1.5 to 3.0 hours. No significant differences were observed between administration routes in the elimination half-life (t(1/2), obtaining mean values ranging from 3.4 to 3.6 hours. The volume of distribution, total clearance, and t(1/2) indicated that almotriptan was extensively distributed and rapidly cleared from the body irrespective of dose or route of administration. The primary route of elimination was renal clearance (approximately 50%-60% of total body clearance). About 65% of the i.v. and s.c. dose and 45% of the oral dose were excreted unchanged in urine in 24 hours, with nearly 90% of this in the first 12 hours. Renal clearance was approximately 2- to 3-fold that of the glomerular filtration rate in man, suggesting that almotriptan is eliminated in part by renal tubular secretion.     

Effect of congestive heart failure on the pharmacokinetics of cibenzoline

Six patients with chronic congestive heart failure (CHF) (New York Heart Association functional class II or III) and five healthy subjects completed this study designed to determine if CHF alters the pharmacokinetics and absolute bioavailability of cibenzoline when compared with healthy subjects. Each subject or patient was administered a one-hour intravenous infusion of 80 mg of 15N2-cibenzoline and simultaneously received an 80-mg oral dose of cibenzoline that allowed for analytic separation of each route of administration. Resulting plasma concentration-time profiles and urinary excretion rate data were used to determine pharmacokinetic parameters for cibenzoline. There were no statistically significant differences in any pharmacokinetic parameter between patients with CHF and healthy subjects. The absolute bioavailability ranged from 74% to 97% in those with CHF. The volume of distribution following the intravenous dose ranged from 3.4 to 6.1 L/kg, and plasma clearance ranged from 245 to 642 mL/min, with an apparent elimination half-life of approximately ten hours. Approximately 60% of the dose was recovered in the urine. Overall, the pharmacokinetics of cibenzoline in patients with chronic CHF do not differ from those observed in healthy subjects.     

The metabolic and pharmacokinetic disposition of mebendazole in the rat

The metabolism and pharmacokinetics of mebendazole was studied in rats using [2'-3H]-mebendazole (biologically stable; specific activity 383.9 (mCi/mMol) and [2-14C]-mebendazole (specific activity 2.57 mCi/mMol). Analyses were performed by high pressure liquid chromatography and liquid scintillation spectrometry. About 85% of an intravenous dose was eliminated with the bile and the remainder with the urine. The majority of the dose was recovered as conjugated metabolites. The major metabolite (methyl-5(6)-(alpha-hydroxybenzyl)-2-benzimidazole carbamate) accounted for about 77% of the total recovered and 99% of it was conjugated. Anaerobic metabolism studies conducted in vitro with intestinal microorganisms obtained from rats indicated that metabolism of mebendazole did not occur in the gut, but that the intestinal microflora was able to hydrolyse conjugated metabolites which were eliminated with the bile. Mebendazole was found to have a biphasic elimination profile after intravenous administration. Its terminal plasma elimination half-life was 3.2 hours and its re-distribution half-life was 0.4 hour. After oral administration, as a solution in aqueous dimethyl sulphoxide, a bioavailability of 53% was obtained.     

Metabolism and disposition of moxonidine in Fischer 344 rats.

The metabolism and disposition of moxonidine (4-chloro-5-(imidazolidin-2-ylidenimino)-6-methoxy-2-methylp yrimidine ), a potent central-acting antihypertensive agent, were investigated in F344 rats. After an i.v. or oral administration of 0.3 mg/kg of [(14)C]moxonidine, the maximum plasma concentrations of moxonidine were determined to be 146.0 and 4.0 ng/ml, respectively, and the elimination half-lives were 0.9 and 1.1 h, respectively. The oral bioavailability of moxonidine was determined to be 5.1%. The metabolic and elimination profiles of moxonidine were determined after an oral administration of 5 mg/kg of [(14)C]moxonidine. More than fifteen phase I and phase II metabolites of moxonidine were identified in the different biological matrices (urine, plasma, and bile). Oxidative metabolism of moxonidine leads to the formation of hydroxymethyl moxonidine and a carboxylic acid metabolite as the major metabolites. Several GSH conjugates, cysteinylglycine conjugates, cysteine conjugates, and a glucuronide conjugate were also identified in rat bile samples. The radiocarbon was eliminated primarily by urinary excretion in rats, with 59.5% of total radioactivity recovered in the urine and 38.4% recovered in the feces within 120 h. In bile duct-cannulated rats, about 39.7% of the radiolabeled dose was excreted in the urine, 32.6% excreted in the bile, and approximately 2% remained in the feces. The results from a quantitative whole body autoradiography study indicate that radiocarbon associated with [(14)C]moxonidine and/or its metabolites was widely distributed to tissues, with the highest levels of radioactivity observed in the kidney and liver. In summary, moxonidine is well absorbed, extensively metabolized, widely distributed into tissues, and rapidly eliminated in rats after oral administration.     

The pharmacokinetics of yohimbine in man

Summary The kinetic disposition of yohimbine was examined in eight young male subjects following a single oral dose of 10 mg yohimbine hydrochloride. The drug was rapidly absorbed (absorption half-time 0.17±0.11 h) and rapidly eliminated from the plasma (elimination half-life 0.60±0.26 h). This clearance of yohimbine from plasma was constant over approximately 10 elimination half-lives, suggesting that distribution into a second pharmacokinetically distinct compartment was not responsible for the rapid decline in plasma yohimbine levels. Urinary excretion and the partitioning of the drug into red blood cells (RBC) was investigated. In the 24 h following oral administration of the drug, virtually no yohimbine was eliminated in the urine (0.35±0.50% of the administered dose). Furthermore, only 20% of blood-borne yohimbine was located in RBC. These results suggest that yohimbine is eliminated primarily through metabolism since the rapid plasma clearance of yohimbine was not the result of renal elimination or sequestration by RBC.     

The Absolute Oral Bioavailability and Population-Based Pharmacokinetic Modelling of a Novel Dipeptidylpeptidase-IV Inhibitor,Vildagliptin, in Healthy Volunteers

BACKGROUND AND OBJECTIVE: Vildagliptin is a potent, selective, orally active inhibitor of dipeptidylpeptidase-IV being developed for the treatment of type 2 diabetes mellitus. The objective of this study was to assess the absolute oral bioavailability of vildagliptin by comparing the systemic exposure after oral and intravenous administration in healthy volunteers. METHODS: This was an open-label, randomised, two-period, two-treatment, crossover study in 11 healthy volunteers. Subjects received vildagliptin 50mg orally or 25mg as a 30-minute intravenous infusion on two occasions separated by a 72-hour washout period. Vildagliptin concentrations were determined by a specific assay in urine (lower limit of quantification [LLQ] = 5 ng/mL) and serial plasma samples (LLQ = 2 ng/mL) obtained up to 24 hours after dosing. Noncompartmental analysis and population pharmacokinetic modelling were performed. RESULTS: Both noncompartmental analysis and population pharmacokinetic modelling estimated the absolute oral bioavailability of vildagliptin to be 85%. Renal elimination of unchanged vildagliptin accounted for 33% and 21% of the administered dose 24 hours after intravenous and oral administration, respectively. Renal clearance (13 L/h) was approximately one-third of the total systemic clearance (41 L/h). Two peaks were observed in plasma concentrations at 1 and 3 hours after oral administration in nine of 11 subjects. Modelling based on the population approach identified two absorption sites with lag-times of 0.225 and 2.46 hours. Both absorption rate constants were slower than the elimination rate constant, indicating 'flip-flop' kinetics after oral administration. Bodyweight was identified as a factor with an impact on the volume of distribution of the peripheral compartment. Clearance was 24% greater in males (44.6 L/h) than in females (36.1 L/h). CONCLUSIONS: Vildagliptin is rapidly and well absorbed with an estimated absolute bioavailability of 85%. Two possible sites of absorption were identified, and the absorption rates were slower than the elimination rate, indicating a flip-flop phenomenon after oral dosing.     

Metabolism of [(14)C]omapatrilat, a sulfhydryl-containing vasopeptidase inhibitor in humans.

Omapatrilat, a potent vasopeptidase inhibitor, is currently under development for the treatment of hypertension and congestive heart failure. This study describes the plasma profile along with isolation and identification of urinary metabolites of omapatrilat from subjects dosed orally with 50 mg of [(14)C]omapatrilat. Only a portion of the radioactivity in plasma was unextractable (40-43%). Prominent metabolites identified in plasma were S-methyl omapatrilat, acyl glucuronide of S-methyl omapatrilat, and S-methyl (S)-2-thio-3-phenylpropionic acid. Omapatrilat accounted for less than 3% of the radioactivity. However, after dithiothreitol reduction all of the radioactivity was extractable and was characterized to be omapatrilat and its hydrolysis product (S)-2-thio-3-phenylpropionic acid, both apparently bound to proteins via reversible disulfide bonds. Urinary profile of radioactivity showed no parent compound but the presence of several metabolites that can be grouped into three categories. 1) Three metabolites, accounting for 56% of the urinary radioactivity, resulted from the hydrolysis of the exocyclic amide bond of omapatrilat. Two metabolites were diastereomers of S-methyl sulfoxide of (S)-2-thio-3-phenylpropionic acid, and the third was the acyl glucuronide of S-methyl (S)-2-thio-3-phenylpropionic acid. 2) One disulfide, identified as the L-cysteine mixed disulfide of omapatrilat, accounted for 8% of the radioactivity in the urine. 3) Five metabolites, derived from omapatrilat, accounted for 30% of the radioactivity in the urine. Two of these metabolites were mixtures of diastereomers of S-methyl sulfoxide of omapatrilat and the third was the S-methyl omapatrilat ring sulfoxide. The other two metabolites were S-methyl omapatrilat and its acyl glucuronide. These results indicate that omapatrilat undergoes extensive metabolism in humans.