Early Detection of Growth Hormone Secretagogue Receptor Antagonists Exploiting Their Atypical Behavior in Competitive Assays.

We report the proof-of-concept of a bioaffinity format designed for the early detection of growth hormone secretagogue receptor (GHS-R1a) antagonists in urine samples. We exploit here their atypical behavior in competitive experiments with labeled ghrelin (GHR), namely, the strong promoting effect on the GHR/GHS-R1a interaction at low molar ratios GHR/antagonist. The antagonists potentiate the GHR/GHS-R1a interaction, and they display the same effect on the interaction of GHS-R1a with other agonists listed as doping agents. The developed assay allows the estimation of affinity constants of ligand/receptor and antagonist/receptor binding and is amenable to optical, electrochemical, and mass-sensitive detection. The estimated affinity constants for GHR/GHS-R1a and antagonist/GHS-R1a in the absence of G proteins are in good agreement with recently reported data.

Population plasma and urine pharmacokinetics of ivabradine and its active metabolite S18982 in healthy Korean volunteers.

Ivabradine, a selective inhibitor of the pacemaker current (If ), is used for heart failure and coronary heart disease and is mainly metabolized to S18982. The purpose of this study was to explore the pharmacokinetics (PK) of ivabradine and S18982 in healthy Korean volunteers. Subjects in a phase I study were randomized to receive 2.5, 5, or 10 mg of ivabradine administered every 12 hours for 4.5 days, and serial plasma and urine concentrations of ivabradine and S18982 were measured. The plasma PK of ivabradine was best described by a 2-compartment model with mixed 0- and first-order absorption, linked to a 2-compartment model for S18982. The introduction of interoccasional variabilities and period as covariate into absorption-related parameters improved the model fit. Urine data have been applied to estimate renal and nonrenal clearance, enabling a more detailed description of the elimination process. We developed a population PK model describing the plasma and urine PK of ivabradine and S18982 in healthy Korean adult males. This model might be useful for predicting the plasma and urine PK of ivabradine, potentially helping to identify the optimal dosing regimens in various clinical situations.

Sensitive and accurate liquid chromatography-tandem mass spectrometry methods for quantitative determination of a novel hepatitis C NS5B inhibitor BMS-791325 and its active metabolite in human plasma and urine.

BMS-791325 is a novel hepatitis C NS5B inhibitor which is currently in clinical development. To support pharmacokinetic (PK) assessments, sensitive, accurate, precise, and reproducible liquid chromatography-tandem mass spectrometry (LC-MS/MS) methods have been developed and validated for the quantitation of BMS-791325 and its active N-demethyl metabolite (BMS-794712) in human plasma and urine. Plasma and urine samples were extracted with methyl-t-butyl ether followed by an LC-MS/MS analysis which was conducted in a multiple reaction monitoring (MRM) mode for the simultaneous detection of the two analytes in human plasma (0.1-50 ng/mL) and in human urine (5-2500 ng/mL). Intra-run precision (3.0% R.S.D.), inter-run precision (5.3% R.S.D.), and accuracy (±4.7% deviation) from plasma and urine quality control samples provide evidence of the methods accuracy and precision. Selectivity, stability in matrices, extraction recovery, matrix effect on LC-MS detection, and interference of coadministered drugs (famotidine and ritonavir) were all acceptable. Reproducibility of the plasma method was demonstrated by reanalysis of a portion of study samples. The results of cross-validations demonstrated the equivalency of two methods validated in two labs. The plasma method was applied to the analysis of several thousand clinical study samples for PK evaluations of the drug in normal healthy subjects and in patients. The urine method was used in the first in human study to evaluate renal clearance and urinary recovery.

On-line column coupled isotachophoresis-capillary zone electrophoresis hyphenated with tandem mass spectrometry in drug analysis: varenicline and its metabolite in human urine.

A new highly advanced analytical approach, based on two-dimensional column coupled CE (ITP-CZE) hyphenated with tandem mass spectrometry (MS/MS, here triple quadrupole, QqQ) was developed, evaluated and applied in biomedical field in the present work. Capillary isotachophoresis (ITP) coupled on-line with capillary zone electrophoresis (CZE) used in hydrodynamically closed separation system was favorable for increasing the sample load capacity, increasing the analyte concentration, and removing the deteriorative highly conductive major matrix constituents. These factors considerably reduced the concentration limits of detection (cLOD) and external sample preparation (comparing to single column CZE), and, by that, provided favorable conditions for the mass spectrometry (enhanced signal to noise ratio, reproducibility of measurements, working life of MS). Here, the CZE-ESI combination provided more effective interfacing than ITP-ESI resulting in both a higher obtainable intensity of MS detection signal of the analyte as well as reproducibility of measurements of the analyte's peak area. The optimized ITP-CZE-ESI-QqQ method was successfully evaluated as for its performance parameters (LOD, LOQ, linearity, precision, recovery/accuracy) and applied for the direct identification and ultratrace (pgmL(-1)) determination of varenicline and, in addition, identification of its targeted metabolite, 2-hydroxy-varenicline, in unpretreated/diluted human urine. This application example demonstrated the real analytical potential of this new analytical approach and, at the same time, served as currently the most effective routine clinical method for varenicline.

Pharmacokinetics and pharmacodynamics of single-dose oral tolvaptan in fasted and non-fasted states in healthy Caucasian and Japanese male subjects.

PURPOSE: To compare the pharmacokinetics and pharmacodynamics of tolvaptan in Caucasian and Japanese healthy male subjects under fasting and non-fasting conditions. METHODS: This was a single-center, parallel-group, randomized, open-label, three-period crossover trial of single oral doses of tolvaptan 30 mg under fasting and non-fasting [a high-fat, high-calorie meal (HFM) or Japanese standard meal] conditions in 25 healthy male Caucasian subjects and 24 healthy male Japanese subjects. Pharmacodynamic endpoints were urine volume and fluid balance for 0 to 24 h postdose. RESULTS: In the fasted state, the plasma tolvaptan C(max) and AUC(∞) geometric mean ratios (90 % confidence interval) were 1.105 (0.845-1.444) and 1.145 (0.843-1.554) for Japanese compared to Caucasian subjects. A HFM increased the C(max) and AUC(∞) values by about 1.15-fold in both Japanese and Caucasian subjects.. Twenty-four-hour urine volumes paralleled pharmacokinetic changes, but the increases were not clinically significant. Fluid balance in the Japanese men was 1.4- to 2.0-fold more negative than that in the Caucasian men. CONCLUSION: Tolvaptan pharmacokinetics is not clinically significantly affected by race. Body weight is a factor that affects exposure. Tolvaptan can be administered with or without food.

Effects of CYP3A4 inhibition and induction on the pharmacokinetics and pharmacodynamics of tolvaptan, a non-peptide AVP antagonist in healthy subjects.

WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT: Before these trials were done, the effects of CYP3A4 inhibition and induction on the pharmacokinetics (PK) and pharmacodynamics (PD) of tolvaptan in healthy subjects were unknown. As tolvaptan is a CYP3A4 substrate, knowing the effects of inhibition and induction on CYP3A4-mediated metabolism was important for dosing recommendations. WHAT THIS STUDY ADDS: This paper describes the changes in tolvaptan PK and PD following inhibition or induction of CYP3A4 and explores the mechanisms behind the disparity seen between tolvaptan PK and effects on urine output. It also discusses the concentrations at which tolvaptan produces its maximal response on urine output and the timing of the onset and offset of this response. AIMS In vitro studies indicated CYP3A4 alone was responsible for tolvaptan metabolism. To determine the effect of a CYP3A4 inhibitor (ketoconazole) and a CYP3A4 inducer (rifampicin) on tolvaptan pharmacokinetics (PK) and pharmacodynamics (PD), two clinical trials were performed. METHODS: For CYP3A4 inhibition, a double-blind, randomized (5:1), placebo-controlled trial was conducted in 24 healthy subjects given either a single 30 mg dose of tolvaptan (n= 19) or matching placebo (n= 5) on day 1 with a 72 h washout followed by a 3 day regimen of 200 mg ketoconazole, once daily with 30 mg tolvaptan or placebo also given on day 5. For CYP3A4 induction, 14 healthy subjects were given a single dose of 240 mg tolvaptan with 48 h washout followed by a 7 day regimen of 600 mg rifampicin, once daily, with 240 mg tolvaptan also given on the seventh day. RESULTS: When co-administered with ketoconazole, mean C(max) and AUC(0,∞) of tolvaptan were increased 3.48- and 5.40-fold, respectively. Twenty-four hour urine volume increased from 5.9 to 7.7 l. Erythromycin breath testing showed no difference following a single dose of tolvaptan. With rifampicin, tolvaptan mean C(max) and AUC were reduced to 0.13- and 0.17-fold of tolvaptan administered alone. Twenty-four hour urine volume decreased from 12.3 to 8.8 l. CONCLUSIONS: Tolvaptan is a sensitive CYP3A4 substrate with no inhibitory activity. Due to the saturable nature of tolvaptan's effect on urine excretion rate, changes in the pharmacokinetic profile of tolvaptan do not produce proportional changes in urine output.

Pharmacokinetics, pharmacodynamics and safety of tolvaptan, a novel, oral, selective nonpeptide AVP V2-receptor antagonist: results of single- and multiple-dose studies in healthy Japanese male volunteers.

PURPOSE: Single- and multiple-dose studies were conducted to assess the pharmacokinetics, pharmacodynamics and safety of tolvaptan in healthy Japanese subjects. METHODS: All studies were single-center, randomized, placebo-controlled, single-blind or double-blind. In an ascending single-dose study, subjects were given a single oral dose of 15-120 mg tolvaptan or placebo. In multiple-dose studies, subjects were given 30, 60, 90 or 120 mg tolvaptan or placebo once daily for 7 days. RESULTS: After a single dose of 15-120 mg tolvaptan, the maximum plasma concentration (C(max)) and the area under the plasma concentration-time curve from zero to time t (AUC(t)) increased dose-dependently, and increases in AUC(t) were dose-proportional. Increases in 24-hour cumulative urine volume were dose- and AUC(24hr)-dependent. Urine excretion rates reached a maximum within 2-4 h after dosing. The maximal urine excretion rates increased dose-dependently, and appeared to reach a plateau at doses ≥ 60 mg. A decrease in urine osmolality and an increase in free water clearance indicated an aquaretic effect of tolvaptan. Serum sodium concentrations were increased by tolvaptan and were higher than that with placebo, even 24 h after dosing, while serum potassium concentrations were unchanged. No tolvaptan accumulation was found after multiple dosing for 7 days. Although 24-hour cumulative urine volume following multiple dosing slightly decreased, a sustained diuretic effect was observed throughout the dosing period. The most common adverse event was mild thirst. CONCLUSIONS: Single and multiple oral doses of tolvaptan exhibited dose-dependent aquaretic effects. Tolvaptan was well tolerated at all doses tested.

Nonclinical pharmacokinetics of a new nonpeptide V2 receptor antagonist, tolvaptan.

PURPOSE: To evaluate the pharmacokinetic profile of tolvaptan. METHOD: The nonclinical pharmacokinetic profile of [(14)C]tolvaptan was evaluated in an absorption, distribution, and excretion study in rats after single oral administration. An in vitro protein binding study was also performed. RESULTS: The tolvaptan-derived radioactivity was rapidly absorbed and extensively distributed to all tissues in rats. The radioactivity levels were greatest in the gastrointestinal tract and liver, though the levels in the cerebrum, cerebellum and medulla oblongata were low. The serum and tissue concentrations of radioactivity, and serum concentration of tolvaptan in male and female rats showed a marked sex difference. The radioactivity was crossed the placenta and was distributed to the fetal tissues in pregnant rats. The milk showed 1.5-15.8-fold higher radioactivity than blood in lactating rats. The radioactivity mainly excreted into the feces via the biliary route. Tolvaptan binds extensively to plasma proteins (≥ 97.2%) in mouse, rat, rabbit, dog and human plasma.

In vitro P-glycoprotein interactions and steady-state pharmacokinetic interactions between tolvaptan and digoxin in healthy subjects.

Interactions between tolvaptan and digoxin were determined in an open-label, sequential study where 14 healthy subjects received tolvaptan 60 mg once daily (QD) on days 1 and 12 to 16 and digoxin 0.25 mg QD on days 5 to 16. Mean maximal concentrations (C(max)) and area under the curve during the dosing interval (AUC(τ)) for digoxin with tolvaptan (day 16) were increased 1.27- and 1.18-fold compared with digoxin alone (day 11); mean renal clearance of digoxin was decreased by 59% (P < .05). Tolvaptan C(max) and AUC(0-24h) for a single dose with digoxin (day 12) were each increased about 10% compared with tolvaptan alone (day 1). Tolvaptan did not accumulate upon multiple dosing. After a single dose of tolvaptan (day 1, day 12), 24-hour urine volume was about 7.5 L. As expected, after 5 days of tolvaptan, 24-hour urine volume decreased about 20%. In vitro studies in control and MDR1-expressing LLC-PK1 cells indicate that tolvaptan is a substrate of P-glycoprotein. Tolvaptan (50 µM) inhibited basolateral to apical digoxin secretion to the same extent as 30 µM verapamil; the IC50 of tolvaptan was determined to be 15.9 µM. The increase in steady-state digoxin concentrations is likely mediated by tolvaptan inhibition of digoxin secretion.

Species differences in the biotransformation of an alpha 4 beta 2 nicotinic acetylcholine receptor partial agonist: the effects of distinct glucuronide metabolites on overall compound disposition.

The metabolism and disposition of (1R,5S)-2,3,4,5-tetrahydro-7-(trifluoromethyl)-1,5-methano-1H-3-benzazepine (1), an alpha(4)beta(2) nicotinic acetylcholine receptor partial agonist, was investigated in Sprague-Dawley rats and cynomolgus monkeys receiving (1R,5S)-2,3,4,5-tetrahydro-7-(trifluoromethyl)-1,5-methano-1H-4[(14)C]-3- benzazepine hydrochloride ([(14)C]1) orally. Although both species chiefly (>or=62%) cleared 1 metabolically, species-specific dispositional profiles were observed for both 1 and total radioactivity. Radioactivity was excreted equally in the urine and feces of intact rats but largely (72%) in bile in bile duct-cannulated animals. In monkeys, radioactivity recoveries were 50-fold greater in urine than feces and minimal (<5%) in bile. Both species metabolized 1 similarly: four-electron oxidation to one of four amino acids or two lactams (minor) and glucuronide formation (major). In rats, the latter pathway predominantly formed an N-carbamoyl glucuronide (M6), exclusively present in bile (69% of dose), whereas in monkeys it afforded an N-O-glucuronide (M5), a minor biliary component (4%) but the major plasma (62%) and urinary (42%) entity. In rats, first-pass hepatic conversion of 1 to M6, which was confirmed in rat hepatocytes, and its biliary secretion resulted in the indirect enterohepatic cycling of 1 via M6 and manifested in double-humped plasma concentration-time curves and long t(1/2) for both 1 and total radioactivity. In monkeys, in which only M5 was formed, double-humped plasma concentration-time curves were absent, and moderate t(1/2) for both 1 and total radioactivity were observed. A seemingly subtle, yet critical, difference in the chemical structures of these two glucuronide metabolites considerably affected the overall disposition of 1 in rats versus monkeys.

Effect of human renal cationic transporter inhibition on the pharmacokinetics of varenicline, a new therapy for smoking cessation: an in vitro-in vivo study.

Varenicline is predominantly eliminated unchanged in urine, and active tubular secretion partially contributes to its renal elimination. Transporter inhibition assays using human embryonic kidney 293 cells transfected with human renal transporters demonstrated that high concentrations of varenicline inhibited substrate uptake by hOCT2 (IC(50)=890 microM), with very weak or no measurable interactions with the other transporters hOAT1, hOAT3, hOCTN1, and hOCTN2. Varenicline was characterized as a moderate-affinity substrate for hOCT2 (K(m)=370 microM) and its hOCT2-mediated uptake was partially inhibited by cimetidine. Co-administration of cimetidine (1,200 mg/day) reduced the renal clearance of varenicline in 12 smokers, resulting in a 29.0% (90% CI: 21.5%-36.9%) increase in systemic exposure. This increase is not considered clinically relevant, as it should not give rise to safety concerns. Consequently, it can be reasonably expected that other inhibitors of hOCT2 would not cause greater renal interactions with varenicline than that seen with the efficient hOCT2 inhibitor cimetidine.

Metabolism and disposition of varenicline, a selective alpha4beta2 acetylcholine receptor partial agonist, in vivo and in vitro.

The metabolism and disposition of varenicline (7,8,9,10-tetrahydro-6,10-methano-6H-pyrazino[2,3-h][3]benzazepine), a partial agonist of the nicotinic acetylcholine receptor for the treatment of tobacco addiction, was examined in rats, mice, monkeys, and humans after oral administration of [14C]varenicline. In the circulation of all species, the majority of drug-related material was composed of unchanged varenicline. In all four species, drug-related material was primarily excreted in the urine. A large percentage was excreted as unchanged parent drug (90, 84, 75, and 81% of the dose in mouse, rat, monkey, and human, respectively). Metabolites observed in excreta arose via N-carbamoyl glucuronidation and oxidation. These metabolites were also observed in the circulation, in addition to metabolites that arose via N-formylation and formation of a novel hexose conjugate. Experiments were conducted using in vitro systems to gain an understanding of the enzymes involved in the formation of the N-carbamoylglucuronide metabolite in humans. N-Carbamoyl glucuronidation was catalyzed by UGT2B7 in human liver microsomes when incubations were conducted under a CO2 atmosphere. The straightforward dispositional profile of varenicline should simplify its use in the clinic as an aid in smoking cessation.

Pharmacokinetic/pharmacodynamic modelling of the disposition and effect of benazepril and benazeprilat in cats.

The disposition and effect of benazepril and its active metabolite, benazeprilat, were evaluated in cats using a pharmacokinetic/pharmacodynamic model. Cats received single 1 mg/kg doses of intravenous 14C-benazeprilat and oral 14C-benazepril.HCl, and single and repeat (eight daily) oral administrations of 0.25, 0.5 and 1.0 mg/kg nonlabelled benazepril.HCl. The pharmacokinetic endpoints were plasma concentrations of benazepril and benazeprilat, and recovery of radioactivity in faeces and urine. The pharmacodynamic endpoint was plasma angiotensin-converting enzyme (ACE) activity. Benazeprilat data were fitted to an equation corresponding to a single-compartment model with a volume equal to the blood space (Vc = 0.093 L/kg). Within this space, benazeprilat was bound nonlinearly to ACE, which was mainly tissular (89.4%) rather than circulating (10.6%). Free benazeprilat was eliminated quickly from the central compartment (t1/2 approximately 1.0 h; Cl approximately 0.125 L/kg/h), elimination being principally biliary ( approximately 85%) rather than urinary ( approximately 15%). Nevertheless, inhibition of ACE was long-lasting (t1/2 16-23 h) due to high affinity binding of benazeprilat to ACE (Kd approximately 3.5 mmol/L, IC50 approximately 4.3 mmol/L). Simulations using the model predict a lack of proportionality between dose of benazepril, plasma benazeprilat concentrations and effect due to the nonlinear binding of benazeprilat to ACE. For example, increasing the dose of benazepril (e.g. above 0.125 mg/kg q24 h) produced only small incremental inhibition of ACE (either peak effect or duration of action).

Effect of renal insufficiency on the pharmacokinetics and pharmacodynamics of benazepril in cats.

The effect of renal insufficiency was studied on the pharmacokinetics (PK) and pharmacodynamics (PD) of the angiotensin-converting enzyme (ACE) inhibitor benazepril in cats. The active metabolite of benazepril, benazeprilat, is eliminated principally ( approximately 85%) via biliary excretion in cats. A total of 20 control animals and 32 cats with moderate renal insufficiency induced by partial nephrectomy were used. Assessments were made at steady state after treatment with placebo or benazepril (0.25-2 mg/kg) once daily for a minimum of 10 days. The PK endpoint was the AUC (0-->24 h) of total plasma benazeprilat. The PD endpoints were systolic, diastolic and mean blood pressures (respectively SBP, DBP and MBP) measured by telemetry, and plasma ACE activity, assessed by an ex vivo assay. Renal function was assessed by glomerular filtration rate (GFR), measured by inulin clearance, and plasma creatinine concentrations (1/PCr). As compared with control animals, the renal insufficient cats had a 78% reduction in GFR (0.57 +/- 0.41 mL/min kg), increased plasma creatinine (2.7 +/- 1.0 mg/dL), urea (44.0 +/- 11.9 mg/dL) and ACE activity, and moderately increased blood pressure (SBP 171.8 +/- 5.1 mmHg) (all parameters P < 0.05). Renal insufficient cats receiving benazepril had significantly (P < 0.05) lower SBP, DBP, MBP and ACE, and higher GFR values as compared with placebo-treated animals. There were no significant differences in SBP, DBP, MBP, benazeprilat or ACE values according to the degree of renal insufficiency in cats receiving benazepril. It is concluded that no dose adjustment of benazepril is necessary in cats with moderate renal insufficiency.

Voltammetric determination of benazepril and ramipril in dosage forms and biological fluids through nitrosation.

A simple and highly sensitive voltammetric method was developed for the determination of benazepril (I) and ramipril (II). The compounds were treated with nitrous acid, and the cathodic current produced by the resulting nitroso derivatives was measured. The voltammetric behavior was studied by adopting direct current (DCt), differential pulse (DPP), and alternating current (ACt) polarography. Both compounds produced well-defined, diffusion-controlled cathodic waves over the whole pH range in Britton-Robinson buffers (BRb). At pH 3 and 5, the values of diffusion-current constants (Id), were 5.90 +/- 0.40 and 6.66 +/- 0.61 for I and II, respectively. The current concentration plots for I were rectilinear over the range of 1.5-40 and 0.1-30 microg/mL in the DCt and DPP modes, respectively; for II, the range was 2-30 and 0.1-20 microg/mL in the DCt and DPP modes, respectively. The minimum detectabilities (S/N = 2) were 0.015 microg/mL (about 3.25 x 10(-8)M) and 0.012 microg/mL (about 2.88 x 10(-8)M) for I and II, respectively, adopting the DPP mode. Results obtained for the proposed method when applied to the determination of both compounds in dosage forms were in good agreement with those obtained using reference methods. Hydrochlorthiazide, which is frequently co-formulated with these drugs, did not interfere with the assay. The method was also applied to the determination of benazepril in spiked human urine and plasma. The percentage recoveries adopting the DPP mode were 96.2 +/- 1.21 and 95.7 +/- 1.61, respectively.

Cardiovascular and renal effects of conivaptan hydrochloride (YM087), a vasopressin V1A and V2 receptor antagonist, in dogs with pacing-induced congestive heart failure.

The systemic hemodynamic and renal responses to conivaptan hydrochloride (YM087; 4'-(2-methyl-1,4,5,6-tetrahydroimidazo[4,5-d][1]benzoazepine -6-carbonyl)-2-phenylbenzanilide monohydrochloride), a vasopressin V1A and V2 receptor antagonist, were determined in pentobarbital-anesthetized dogs after 2 to 3 weeks of rapid right ventricular pacing. Congestive heart failure, characterized by decreases in first derivative of left ventricular pressure (left ventricular d P/dt(max)) and cardiac output, and increases in left ventricular end-diastolic pressure and total peripheral vascular resistance, was induced by chronic rapid right ventricular pacing at 260-280 beats/min. Intravenous administration of conivaptan (0.1 mg/kg) significantly increased left ventricular dP/dt(max) and cardiac output and significantly decreased left ventricular end-diastolic pressure and total peripheral vascular resistance. Conivaptan also increased urine flow and reduced urine osmolality by markedly increasing free water clearance. These results indicate that conivaptan produced hemodynamic improvement and marked aquaresis in dogs with congestive heart failure. Therefore, conivaptan may find clinical use in treating patients with congestive heart failure.

Determination of ivabradine and its N-demethylated metabolite in human plasma and urine, and in rat and dog plasma by a validated high-performance liquid chromatographic method with fluorescence detection.

A sensitive and selective high-performance liquid chromatographic method with native detection of fluorescence was developed and validated for the quantitation of ivabradine and its N-demethylated metabolite in plasma (rat, dog, human) and human urine. The procedure involves the use of an analogue as internal standard, solid-phase extraction on cyano cartridges, separation on a Nova-Pak C8 column and fluorescence detection. Calibration curves are linear in the concentration ranges from 0.5 to 100 ng/ml in plasma and 2.0 to 500 ng/ml in urine with a limit of quantitation set at 0.5 and 2.0 ng/ml in plasma and urine, respectively. The analysis of plasma and urine samples (spiked with the analytes at low, medium and high concentrations of the calibration range) demonstrates that both analytes can be measured with precision and accuracy within acceptable limits. Quality controls spiked with analyte concentrations up to 10000 ng/ml can also be analysed with excellent precision and accuracy after dilution of the samples. The parent drug and its metabolite are stable in plasma and urine after short-term storage (24 h at room temperature and after three freeze-thaw cycles) as well as after long-term storage at -20 degrees C (at least 6 months in animal plasma and 12 months in human plasma and urine). The method has been used to quantify both compounds in plasma and urine samples from clinical and non-clinical studies with ivabradine.

The absence of a pharmacokinetic interaction between aspirin and the angiotensin-converting enzyme inhibitor benazepril in healthy volunteers.

Potential effects of the coadministration of single doses of aspirin (325 mg) and of benazepril hydrochloride (20 mg) on the pharmacokinetics and the metabolism of these two drugs were evaluated in 12 healthy subjects. Plasma concentration profiles of benazepril, its active metabolite benazeprilat, and total salicylic acid were determined together with urinary excretion of benazeprilat, salicylic acid, salicyluric acid, and salicylate glucuronides. Almost superimposable plasma profiles of benazepril, benazeprilat, and total salicylic acid were achieved with the drugs given alone and concomitantly. The coadministration of benazepril hydrochloride and aspirin did not modify the pharmacokinetics or the metabolism of the two drugs.

The disposition of [14C]-labelled benazepril HCl in normal adult volunteers after single and repeated oral dose.

1. The disposition of [14C]-labelled benazepril HCl, an ACE-inhibitor, was studied in four normal adult volunteers after a single oral dose of 20 mg and after repeated doses of 20 mg once daily for 5 days. Radioactivity was measured in plasma, urine and faeces. The prodrug ester benazepril and the pharmacologically active metabolite benazeprilat were determined quantitatively in plasma and urine by a g.c.-m.s. method. The pattern of metabolites in urine was analysed semiquantitatively by h.p.l.c.-radiometry. 2. After a single oral dose at least 37% was absorbed, as indicated by urinary recovery. The peak plasma concentration of benazepril (0.58 +/- 0.13 nmol/g (SD] was observed at 0.5h after dose, indicating rapid absorption. Peak concentrations of radioactivity (1.88 +/- 0.48 nmol/g) and of active benazeprilat (0.84 +/- 0.25 nmol/g) were observed at 1 h after dose, demonstrating rapid bioactivation. 3. The area under the plasma curve (AUC0-96 h) of total radioactivity amounted to 9.7 +/- 1.1 (nmol/g)h, 5% of which was accounted for by benazepril and about 50% by benazeprilat. 4. Over 9 days 96.8 +/- 0.5% of the dose was excreted in urine and faeces. Urinary excretion accounted for 37.0 +/- 6.0% of the dose, 80% of which was recovered in the first 8 h after dosing. 5. In urine, only 0.4% of the dose (1% of the radioactivity) was excreted as unchanged benazepril, indicating that the compound was extensively metabolized. Benazeprilat accounted for 17% of the dose (about half of the radioactivity; 0-96 h). Glucuronide conjugates of benazepril and benazeprilat constituting approximately 11% and 22% of the radioactivity (about 4% and 8% of the dose; 0-48 h) were tentatively identified. 6. Repeated oral treatment with benazepril HCl did not influence the pharmacologically relevant kinetics and disposition parameters.

Disposition and metabolism of the angiotensin-converting enzyme inhibitor [4S-[4 alpha, 7 alpha, (R*), 12b beta]]-7-[S-(1-ethoxycarbonyl-3- phenylpropyl)amino]-1,2,3,4,6,7,8,12b-octahydro-6-oxo- pyrido[2,1-a][2]benzazepine-4-carboxylic acid in monkeys and dogs.

[4S-[4 alpha, 7 alpha, (R*),12b beta]]-7-[S- (1-ethoxycarbonyl-3-phenylpropyl)amino]-1,2,3,4,6,7,8, 12b-octahydro-6-oxo-pyrido[2,1-a][2]benzazepine-4-carboxylic acid (MDL 27,210) is the ethyl ester prodrug of a potent angiotensin-converting enzyme inhibitor, MDL 27,088. After a single dose of [14C]MDL 27,210 (3 mg/kg iv), MDL 27,210 was rapidly eliminated from the plasma of monkeys and dogs with a terminal half-life of approximately 0.3 hr. The steady-state volume of distribution was 0.15 liter/kg in dogs and 0.28 liter/kg in monkeys. Monkeys excreted 52% of the 14C dose in the feces and 41% in the urine; dogs excreted 80% of the 14C dose in the feces and 14% in the urine. The presence of a large fraction of the 14C dose in the feces of both species following iv administration suggests that significant biliary excretion occurred. MDL 27,210 administered iv to monkeys and dogs was rapidly and extensively (greater than 99.9%) metabolized, primarily to its diacid metabolite, MDL 27,088. The half-life of MDL 27,088 was 2.2 hr in dogs and 3.6 hr in monkeys.