Formation and elimination of sulphamethoxazole hydroxylamine after oral administration of sulphamethoxazole.

The formation and elimination of sulphamethoxazole hydroxylamine in relation to the pharmacokinetics of the parent compound and its N4-acetyl metabolite were investigated in six healthy subjects after a single oral dose of 800 mg sulphamethoxazole. The apparent half-lives of sulphamethoxazole and its metabolites were approximately 10 h, indicative of formation rate-limited metabolism. The mean residence time of the hydroxylamine metabolite was 5.5 +/- 1.5 h. The renal clearance of sulphamethoxazole hydroxylamine was 4.39 +/- 0.91 l h-1. The urinary recovery of sulphamethoxazole accounted for 16.5 +/- 5.5% of the dose, N4-acetyl-sulphamethoxazole for 46.2 +/- 6.6% and the hydroxylamine metabolite for 2.4 +/- 0.8%. The remaining 35% of the dose was unaccounted for. Acetylator phenotype was determined using sulphadimidine. The renal excretion of sulphamethoxazole hydroxylamine was 1.9 +/- 0.9% in slow acetylators (n = 3) and 2.8 +/- 0.3% in fast acetylators (n = 3); for N4-acetyl-sulphamethoxazole the values were 48 +/- 6% and 44 +/- 8%, respectively. Sulphamethoxazole is metabolized, although to a limited extent, to a hydroxylamine metabolite. This metabolite may be important for the pathogenesis of adverse reactions.     

Elimination of cocaine and metabolites in plasma, saliva, and urine following repeated oral administration to human volunteers

Chronic administration of lipophilic drugs can result in accumulation and prolonged elimination during abstinence. It has been suggested that cocaine and/or metabolites can be detected in saliva and urine for an extended period following long-term, high-dose administration. The effects of chronic oral cocaine administration in healthy volunteer subjects with a history of cocaine abuse were investigated. Subjects were housed on a closed clinical ward and were administered oral cocaine in up to 16 daily sessions. In each session, volunteers received five equal doses of oral cocaine with 1 h between doses. Across sessions, cocaine was administered in ascending doses from an initial dose of 100 mg (500 mg/day) up to 400 mg (2 g/day), increasing by 25 mg/dose/session (125 mg/session). Participation in the study was terminated if cardiovascular safety parameters were exceeded. Plasma and saliva specimens were collected periodically during the dosing sessions and during the one-week withdrawal phase at the end of the study. All urine specimens were collected throughout the entire study. Specimens were analyzed for cocaine and metabolites by solid-phase extraction followed by gas chromatographic-mass spectrometric analysis in the SIM mode. The limit of detection for each analyte was approximately 1 ng/mL. The analytes measured included benzoylecgonine (BZE), ecgonine methyl ester, cocaine, benzoylnorecgonine, norcocaine, m- and p-hydroxycocaine, and m- and p-hydroxybenzoylecgonine. Noncompartmental analysis was employed for the determination of plasma and saliva pharmacokinetic parameters. Urinary elimination half-lives for cocaine and metabolites were determined by constructing ARE (amount remaining to be excreted) plots. Two phases of urinary elimination of cocaine and metabolites were observed. An initial elimination phase was observed during withdrawal that was similar to the elimination pattern observed after acute dosing. The mean (N = 6) plasma, saliva, and urine cocaine elimination half-lives were 1.5 +/- 0.1 h, 1.2 +/- 0.2 h, and 4.1 +/- 0.9 h, respectively. For three subjects, the mean cocaine urinary elimination half-life for the terminal phase was 19.0 +/- 4.2 h. There was some difficulty in determining if a terminal elimination phase for cocaine was present for the remaining three subjects because of interference by high concentrations of BZE. A terminal elimination phase was also observed for cocaine metabolites with half-life estimates ranging from 14.6 to 52.4 h. These terminal elimination half-lives greatly exceeded previous estimates from studies of acute cocaine administration. These data suggest that cocaine accumulates in the body with chronic use resulting in a prolonged terminal elimination phase for cocaine and metabolites.     

Pharmacokinetics of morphine and its surrogates. III: Morphine and morphine 3-monoglucuronide pharmacokinetics in the dog as a function of dose.

The pharmacokinetics of morphine and its derived metabolite, morphine 3-monoglucuronide, were studied in normal and bile-cannulated dogs. High doses (7.2-7.7 mg/kg iv) caused renal and biliary shutdowns and time lags in urinary drug and metabolite excretion and in biliary secretion of the hepatically formed conjugate. Intermediate doses (0.41-0.47 mg/kg iv) inhibited urine flow but not renal clearance. Low doses (0.019-0.07 mg/kg iv) had no apparent effect. Dose-related effects on the total, metabolic, and biliary clearances imply saturable enzymes and/or dose-inhibited hepatic flows, accounting for the major elimination half-lives of 83 +/- 8 and 37 +/- 13 min at the high and low doses, respectively. The slow terminal phase in plasma morphine and metabolite elimination and urinary accumulation is due apparently to the enterohepatic metabolite recirculation after biliary excretion, gastrointestinal hydrolysis, and hepatic first-pass reconjugation. Bile-cannulated dogs showed no fecal drug and no slow terminal plasma and urine elimination phases. Intravenous morphine 3-monoglucuronide was eliminated only renally and showed neither biliary excretion nor prolonged hepatically formed glucuronide elimination. Hepatic morphine clearances at normal therapeutic doses parallel hepatic blood flow and explain the lack of oral morphine bioavailability by anticipating complete first-pass liver metabolism. Renal morphine and morphine conjugate clearances were 85 (+/- 9 SEM) and 41 (+/- 4 SEM) ml/min, respectively, indicating glomerular filtration for the latter and glomerular filtration plus tubular secretion for the former. Urinary morphine and morphine conjugate excretion accounted for approximately to 83% of the dose. Biliary secretion accounted for 11-14% of the dose. Morphine showed dose-independent plasma protein binding of 36 (+/- 1 SEM) % and a red cell-plasma water partition coefficient of 1.11 +/- 0.04 SD. New equations were developed to model the discontinuous morphine and morphine metabolite pharmacokinetics.     

Pharmacokinetics and biotransformation of diethylene glycol and ethylene glycol in the rat

1. 14C-Diethylene glycol (DEG), administered orally to rats at 1, 5, and 10 ml/kg, gave elimination half-lives of 6, 6, and 10 h, respectively, from urinary excretion data. Half-logarithmic plots of urinary 14C excretion rates versus time indicated zero-order elimination for the first 9 and 18 h after oral doses of 5 and 10 ml of 14C-DEG/kg, respectively. 14C-DEG urinary elimination kinetics changed into first-order 6, 9, and 18 h after oral doses of 1, 5, and 10 ml/kg, with a half-life of 3 h. 2. After oral doses of 3 and 5 ml ethylene glycol (EG)/kg, half-lives of 4.5 and 4.1 h were estimated from cumulative urinary excretion data for non-metabolized EG. A half-life of 2 h was determined from half-logarithmic plots of urinary excretion rates of non-metabolized EG after the same oral doses of EG. 3. The urinary concentrations of non-metabolized DEG and its metabolite, 2-hydroxyethoxyacetic acid (2-HEAA), determined by high-resolution n.m.r. spectroscopy in the urine of rats doses with DEG were 61-68% and 16-31% dose, respectively. 4. Urinary concentrations of non-metabolized EG and its metabolite, glycolic acid (GA), determined by n.m.r., gave 62-67% for non-metabolized EG and 28.7% for GA following oral doses of EG. 5. Oxidation of DEG and EG in rats was accompanied by a change of urinary pH, reflecting metabolic acidosis. 6. Comparison of the KM for DEG oxidation in vitro by ADH with that of ethanol oxidation, showed a 680-fold difference in substrate affinity. DEG inhibited ethanol oxidation non-competitively, the Ki being 0.44 M.     

Urinary pharmacokinetics of methamphetamine and its metabolite, amphetamine following controlled oral administration to humans

Methamphetamine is widely abused for its euphoric effects. Our objectives were to characterize the urinary pharmacokinetics of methamphetamine and amphetamine after controlled methamphetamine administration to humans and to improve the interpretation of urine drug test results. Participants (n = 8) received 4 daily 10-mg (low) oral doses of sustained-release (d)-methamphetamine hydrochloride within 7 days. After 4 weeks, 5 participants received 4 daily 20-mg (high) oral doses. All urine specimens were collected during the study. Methamphetamine and amphetamine were measured by GC-MS/PCI. Maximum excretion rates ranged from 403 to 4919 microg/h for methamphetamine and 59 to 735 microg/h for amphetamine with no relationship between dose and excretion rate. The mean molar percentage of dose in the urine as total methamphetamine and amphetamine were 57.5 +/- 21.7% (low dose) and 40.9 +/- 8.5% (high dose). Mean urinary terminal elimination half-lives across doses were 23.6 +/- 6.6 hours for methamphetamine and 20.7 +/- 7.3 hours for amphetamine. Methamphetamine renal clearance across doses was 175 +/- 102 mL/min. The mean amphetamine/methamphetamine percentage ratio based on the area under the urinary excretion-time curve increased over time from 13.4 +/- 6.5% to 35.7 +/- 26.6%. Slow urinary excretion results in drug accumulation and increases in detection time windows. Our findings also support the presence of an active renal excretion mechanism for methamphetamine.     

Pharmacokinetics of orally administered hexobarbital in plasma and saliva of healthy subjects

Hexobarbital (HB) concentrations were determined in plasma and saliva of 8 healthy subjects, following oral administration of 500 mg HB-Na. Mean plasma half-lives were 3.2 +/- 0.1 h, and salivary half-lives 3.3 +/- 0.2 h. Mean plasma clearance was 22.9 +/- 2.3 1 h-1. There was a linear relationship between HB concentrations in saliva and plasma (r = 0.92). Mean salivary levels were 34 per cent of plasma levels. Salivary pH was constant throughout the experiment, 7.06 +/- 0.09. There was an inconsistent tendency of the saliva over plasma ratios to increase as a function of time. The percentage of protein binding calculated from saliva over plasma ratios was in reasonable agreement with in vitro data of equilibrium dialysis, 64.1 +/- 2.6 per cent and 65.9 +/- 0.8 per cent, respectively. The experiment was repeated in 4 subjects, and considerable intraindividual differences were shown to exist in saliva over plasma ratio, half-lives, and protein binding. It was concluded that HB elimination half-lives can relatively accurately be determined from salivary concentrations. Oral plasma clearance can only be estimated if the individual saliva over plasma ratios are known; this would require the taking of at least one blood sample during the experiment. When employing HB as a model substrate for drug metabolizing enzyme activity in vivo, the determination of its pharmacokinetic parameters, particularly oral plasma clearance as a reflection of cytochrome P-450 activity, cannot be achieved by taking saliva samples only.     

Disposition of hexobarbitone in healthy man: kinetics of parent drug and metabolites following oral administration.

1 Hexobarbitone plasma kinetics were determined in six healthy volunteers, who received 500 mg hexobarbitone orally. In addition urinary excretion rate and cumulative excretion were measured of its three major metabolites: 3'-hydroxyhexobarbitone, 3'-ketohexobarbitone and 1,5-dimethylbarbituric acid. 2 The mean plasma elimination half-life of hexobarbitone was 3.7 +/- 0.9 h (n = 6). Assuming complete absorption, the volume of distribution and the metabolic clearance were 81.3 +/- 20.5 1 and 16.4 +/- 2.9 1/h, respectively. The mean maximal plasma concentration was 7.1 +/- 2.1 micrograms/ml and was reached 1.2 +/- 0.4 h after drug administration. 3 3'-Hydroxyhexobarbitone and 3'-ketohexobarbitone, which are products of allylic side-chain oxidation of hexobarbitone, were excreted in 24 h to the extent of 4.7 +/- 1.3 and 32.1 +/- 11.9% of the dose, respectively. In the same period, 1,5-dimethylbarbituric acid, which is the end product of the epoxide-diol pathway, was excreted to 18.0 +/- 7.8% of the dose. The ratio of the sum of 3'-hydroxy- and 3'-ketohexobarbitone vs 1,5-dimethylbarbituric acid excreted varied with time and amounted ultimately in 24 h urine to 2.3 +/- 1.0. 4 The half-lives of 3'-hydroxyhexobarbitone and 1,5-dimethylbarbituric acid, calculated from their renal excretion rate curves, amounted 5.2 +/- 0.9 and 6.6 +/- 1.3 h and were significantly longer than the half-life of hexobarbitone in plasma. The half-life of 3'-ketohexobarbitone was 4.2 +/- 0.8 h. The maximum excretion rate of 1,5-dimethylbarbituric acid was reached at 7.7 +/- 1.0 h after administration of hexobarbitone. 3'-Hydroxy- and 3'-ketohexobarbitone were excreted with a maximal rate at 2.2 +/- 0.8 and 2.8 +/- 0.4 h respectively.     

Antipyrine metabolite formation in children in the acute phase of malnutrition and after recovery.

1. The plasma elimination rate of antipyrine and the urinary excretion of antipyrine and its primary metabolites 4-hydroxy-antipyrine, norantipyrine, 3-hydroxymethyl-antipyrine and 3-carboxyantipyrine were measured in five children in the acute phase of malnutrition and after recovery. The results were compared with those obtained in 3 normal children. 2. Upon nutritional rehabilitation antipyrine clearance increased from 0.65 +/- 0.14 ml min-1 kg-1 to 1.07 +/- 0.20 ml min-1 kg-1. 3. The urinary excretion of 4-hydroxy-antipyrine increased from 6.1 +/- 4.5 to 14.7 +/- 5.9%, norantipyrine from 8.8 +/- 5.7 to 14.3 +/- 5.4 and 3-hydroxy-methyl-antipyrine from 11.8 +/- 8.3 to 20.5 +/- 5.6% (% of dose/24h urine). Excretion of unchanged antipyrine decreased from 5.2 +/- 3.7 to 2.7 +/- 0.9% dose. The metabolite profile (ratio between the amounts of the various metabolites excreted) was not significantly different. 4. It is concluded that malnutrition decreases the rate of antipyrine metabolism, but it does not affect the three oxidative pathways differently.     

Disposition and effect of the new thromboxane synthetase inhibitor 6-(1-imidazolylmethyl)-5,6,7,8-tetrahydronaphthalene-2-carboxylic acid in man

The disposition of a new thromboxane synthetase inhibitor, 6-(1-imidazolylmethyl)-5,6,7,8-tetrahydronaphthalene-2-carboxylic acid (DP-1904) upon administration of a single 200-mg oral dose to normal Japanese volunteers was studied. DP-1904 proved to be rapidly absorbed from the gastrointestinal tract and converted to its ester glucuronide, which appeared in plasma within 30 min after dosing. The AUCs of DP-1904 and its ester glucuronide were 7.23 +/- 0.54 and 7.93 +/- 0.86 micrograms.h/ml (mean +/- S.E., n = 5), respectively. Both compounds were also eliminated very rapidly from the body (half-lives greater than 60 min). The primary route of elimination was renal, with 52.1 +/- 2.2 and 37.6 +/- 1.6% of the dose being excreted in the urine as the unchanged form and the glucuronide conjugate within 48 h, respectively. The cumulative fecal excretion rates of DP-1904 up to 48 h after dosing were approximately 0.5%. The main metabolite of DP-1904 in humans was DP-1904 glucuronide. Serum thromboxane (TX) B2 levels were reduced more than 98% within 1 h after dosing. There was still more than 75% suppression of serum TXB2 levels at 12 h after dosing. At 72 h TXB2 concentrations returned to control levels. These data indicate that DP-1904 is a potent and long-acting thromboxane synthetase inhibitor.     

Pharmacokinetics, metabolism, and excretion of irinotecan (CPT-11) following I.V. infusion of [(14)C]CPT-11 in cancer patients.

This study determined the disposition of irinotecan hydrochloride trihydrate (CPT-11) after i.v. infusion of 125 mg/m(2) (100 microCi) [(14)C]CPT-11 in eight patients with solid tumors. Mean +/- S.D. recovery of radioactivity in urine and feces was 95.8 +/- 2.7% (range 92.2-100.3%, n = 7) of dose. Radioactivity in blood, plasma, urine, and feces was determined for at least 168 h after dosing. Fecal excretion accounted for 63.7 +/- 6.8 (range 54.2-74.9%, n = 7) of dose, whereas urinary excretion accounted for 32.1 +/- 6.9% (range 21.7-43.8%; n = 7) of dose. One patient with a biliary T-tube excreted 30.1% of dose in bile, 14.2% in feces, and 48.2% in urine. Quantitative radiometric HPLC revealed that CPT-11 was the major excretion product in urine, bile, and feces. Aminopentane carboxylic acid (APC) and SN-38 glucuronide (SN-38G) were the most significant metabolites in urine and bile, whereas SN-38 and NPC, a primary amine metabolite, were relatively minor excretion products. SN-38 and APC were the most significant metabolites in feces. The relatively higher amount of SN-38 in feces compared with bile is presumably due to hydrolysis of SN-38G to SN-38 by enteric bacterial beta-glucuronidases. There was close correspondence between quantitative fluorescence HPLC and mass balance findings. CPT-11 was the major circulating component in plasma (55% of the mean radiochemical area under the curve), and CPT-11, SN-38, SN-38G, and APC accounted for 93% of the mean radiochemical AUC. These results show that the parent drug and its three major metabolites account for virtually all CPT-11 disposition, with fecal excretion representing the major elimination pathway.     

Studies of the different metabolic pathways of antipyrine in man

Summary The pharmacokinetics of antipyrine in plasma and saliva, and urinary excretion of its major metabolites, were studied following i.v. and oral administration of antipyrine 500 mg to 6 healthy volunteers. Data from both plasma and saliva showed that the oral bioavailability of antipyrine given as an aqueous solution was complete. The saliva/plasma concentration ratio was constant with time from about 3 h onwards, with a mean value of 0.87 after oral and 0.91 after i.v. administration. It is concluded that the pharmacokinetic parameters of antipyrine can be satisfactorily established on the basis of salivary data, although the volume of distribution and clearance values are then slightly too high. After i.v. administration, 3.8±1.9% of the dose was excreted in urine as unchanged antipyrine in 48h, 24.9±6.3% as 4-hydroxyantipyrine, 16.5±3.2% as norantipyrine, 13.0±2.2% as 3-hydroxymethyl-antipyrine and 5.8±1.0% as 3-carboxy-antipyrine. No significant differences were observed following oral administration. The half-lives calculated from the linear part of the urinary excretion rate curves of the metabolites were about the same for oral and i.v. administration, and were of the same order of magnitude as the elimination half-life of parent drug in plasma and saliva. It is important for determination of the ultimate metabolite ratio that urine is collected for at least 36h, because there is a delay in the excretion of 3-hydroxymethyl-antipyrine in urine.     

Glyceryl-1-nitrate pharmacokinetics in healthy volunteers.

The plasma kinetics and urinary excretion of glyceryl-1-nitrate (G-1-N), a metabolite of glyceryl trinitrate with antianginal potential, were investigated in 10 healthy male volunteers, after intravenous infusion and oral administration of 20 mg G-1-N. The apparent volume of G-1-N distribution was 601 corresponding to 0.761 kg-1 body weight, on average. It is suggested that total body water is the principal biological correlate of the hydrophilic drug. Mean intravenous clearance was 283 ml min-1 or 3.61 ml min-1 kg-1. The average of elimination half-lives were 2.50 +/- 0.36 (s.d.) h after the intravenous and 2.54 +/- 0.40 (s.d.) h after the oral dose. Inter-subject variances of pharmacokinetic parameters were low compared to variances reported for glyceryl trinitrate. The coefficient of intra-subject variation of the elimination half-lives was 8.8%. 5.5% (i.v.) and 5.4% (p.o.) of the administered dose were excreted into urine up to 48 h after the administration. 1% (i.v.) and 1.5% (p.o.) were in the conjugated form. The oral dose was rapidly and almost completely absorbed. The oral bioavailability on the basis of areas under the curve amounted to 88.6% on the average. For clinical use, owing to its high oral bioavailability, long residence in the body, inactivation by metabolic conversion, and good predictability of kinetic parameters, G-1-N offers advantage over glyceryl trinitrate.     

Lack of relationship between glibenclamide metabolism and debrisoquine or mephenytoin hydroxylation phenotypes.

The pharmacokinetics of a single oral dose of 1.75 mg glibenclamide were studied in 15 healthy Caucasians including five poor metabolisers of debrisoquine and five poor metabolisers of S-mephenytoin. Plasma glibenclamide concentrations and the urinary concentrations of trans-4- and cis-3-hydroxyglibenclamide were analyzed by h.p.l.c. Thirty-six +/- 6% (mean +/- s.d., n = 15) of the given dose of glibenclamide was excreted in 48 h urine as hydroxylated metabolites, 27 +/- 4% as trans-4-hydroxyglibenclamide and 8 +/- 2% as cis-3-hydroxyglibenclamide. There were no differences in the plasma pharmacokinetics of glibenclamide or in the urinary excretion of the metabolites between poor and extensive metabolisers of debrisoquine, neither between the two mephenytoin hydroxylator phenotypes. The study thus indicates that the disposition of glibenclamide is not influenced by these two independent polymorphisms of drug oxidation.     

Single-dose kinetics of an enteric-coated formulation of carbamazepine-10,11-epoxide, an active metabolite of carbamazepine

The kinetics of an enteric-coated formulation of carbamazepine-10,11-epoxide (CBZ-E) were studied in healthy subjects. A single oral dose of 100 mg of CBZ-E was given to eight subjects. Four of them were also given a single oral dose of 200 mg of CBZ-E. Plasma concentrations of CBZ-E and urinary excretion of the end metabolite trans-10,11-dihydroxy-10,11-dihydro-carbamazepine (trans-CBZ-diol) were determined by high performance liquid chromatography. Plasma kinetics of CBZ-E fitted an open one-compartment model with plasma elimination half-life of 7.4 +/- 1.8 h (mean +/- SD). The clearance was 105 +/- 17 ml/kg/h and the apparent volume of distribution 1.1 +/- 0.2 L/kg assuming complete bioavailability. There was no indication of dose-dependent elimination of CBZ-E. The recovery of trans-CBZ-diol in urine collected for 3 days was 67 +/- 9% of the given dose. This enteric-coated formulation may thus in the future be used for the evaluation of the clinical effects of CBZ-E in patients.     

Flecainide: single and multiple oral dose kinetics, absolute bioavailability and effect of food and antacid in man.

The kinetics of flecainide after single intravenous (2 mg kg-1) and oral (200 mg) dosing, absolute bioavailability, effects of food and aluminium hydroxide on flecainide absorption and steady-state kinetics following twice daily oral dosing (200 mg) have been evaluated in ten healthy subjects. Absolute bioavailability of oral flecainide averaged 70% (range 60-86%). Rate and extent of flecainide absorption were not significantly affected by food nor by concomitantly administered aluminium hydroxide. The apparent volume of distribution of 5.5 +/- 0.3 l kg-1 indicates wide distribution of flecainide in tissues. Estimated elimination half-lives from plasma data averaged 9.3 to 12.4 h (single oral dose studies), 11.8 h (single i.v. dose), and 11.5 h (multiple oral dose). Half-lives calculated from urinary excretion data corresponded well with those calculated from plasma data. Flecainide elimination takes place both by nonrenal (metabolic) clearance and renal excretion of the intact drug involving glomerular filtration and active tubular secretion. Following i.v. dosing CLNR and CLR averaged respectively 3.24 +/- 0.80 and 2.38 +/- 0.49 ml min-1 kg-1. After 200 mg twice daily oral treatment steady state was reached within 3-4 days with trough and peak plasma levels on day 8 of 457 and 662 ng ml-1, which are well within the therapeutic range.     

The metabolic fate of 11-bromo[15-3H]vincamine in man

During 5 days following a single oral dose of 3H-11-bromovincamine (40 mg) to two human subjects, means of 55% and 27% of the 3H dose were excreted in the urine and faeces respectively, mainly within 24 and 48 h. Mean plasma concentrations of 3H reached a peak (1900 ng equiv./ml) at 1 h after dosing and declined biphasically with half-lives of 5 h and 11 h which were similar to half-lives for urinary excretion of 3H. Parent drug and 11-bromovincaminic acid were the major dose-related components in plasma at 1.5 and 3 h. Mean plasma concentrations of 11-bromovincamine reached a peak (620 ng/ml) at 0.75 h and declined biphasically with half-lives of about 1 h and 5 h. The major urinary metabolite was 11-bromovincaminic acid (31% dose). Also present in urine were 11-bromovincamine (3%), 11-bromoapovincamine (1%) and 2 unknown metabolites (9% and 6%). Similar metabolites were detected in faecal extracts. If inadequately stored in biological samples, 11-bromovincamine could be hydrolysed to 11-bromovincaminic acid and be epimerised to 11-bromo-epivincamine.     

Metabolism and disposition of imatinib mesylate in healthy volunteers.

Imatinib mesylate (GLEEVEC, GLIVEC, formerly STI571) has demonstrated unprecedented efficacy as first-line therapy for treatment for all phases of chronic myelogenous leukemia and metastatic and unresectable malignant gastrointestinal stromal tumors. Disposition and biotransformation of imatinib were studied in four male healthy volunteers after a single oral dose of 239 mg of (14)C-labeled imatinib mesylate. Biological fluids were analyzed for total radioactivity, imatinib, and its main metabolite CGP74588. Metabolite patterns were determined by radio-high-performance liquid chromatography with off-line microplate solid scintillation counting and characterized by liquid chromatography-mass spectrometry. Imatinib treatment was well tolerated without serious adverse events. Absorption was rapid (t(max) 1-2 h) and complete with imatinib as the major radioactive compound in plasma. Maximum plasma concentrations were 0.921 +/- 0.095 mug/ml (mean +/- S.D., n = 4) for imatinib and 0.115 +/- 0.026 mug/ml for the pharmacologically active N-desmethyl metabolite (CGP74588). Mean plasma terminal elimination half-lives were 13.5 +/- 0.9 h for imatinib, 20.6 +/- 1.7 h for CGP74588, and 57.3 +/- 12.5 h for (14)C radioactivity. Imatinib was predominantly cleared through oxidative metabolism. Approximately 65 and 9% of total systemic exposure [AUC(0-24 h) (area under the concentration time curve) of radioactivity] corresponded to imatinib and CGP74588, respectively. The remaining proportion corresponded mainly to oxidized derivatives of imatinib and CGP74588. Imatinib and its metabolites were excreted predominantly via the biliary-fecal route. Excretion of radioactivity was slow with a mean radiocarbon recovery of 80% within 7 days (67% in feces, 13% in urine). Approximately 28 and 13% of the dose in the excreta corresponded to imatinib and CGP74588, respectively.     

Pharmacokinetics of the angiotensin converting enzyme inhibitor benazepril.HCl (CGS 14 824 A) in healthy volunteers after single and repeated administration

The pharmacokinetics of the new angiotensin converting enzyme (ACE) inhibitor benazepril.HCl were evaluated in healthy male volunteers. The single dose kinetics were established from data of 62 subjects receiving an oral 10 mg dose of the drug. The steady state kinetics were investigated in 15 subjects after once-daily oral doses of 5, 10 or 20 mg. The compound is a prodrug which, on absorption, is hydrolysed to the pharmacologically active metabolite benazeprilat. Thus, plasma concentrations and urinary excretion of parent compound and active metabolite were determined. Benazepril.HCl was rapidly absorbed (tmax = 0.5 h) and rapidly eliminated from plasma (t1/2 = 0.6 h). Only trace amounts were excreted unchanged in urine. The drug was rapidly metabolized to benazeprilat (tmax = 1.5 h). The elimination of the metabolite from plasma was biphasic. About 80 per cent of benazeprilat formed was eliminated within 24 h (t 1/2 = 2.7 h), whereas the terminal phase (t1/2 = 22.3 h) controlled a minor amount of elimination. About 17 per cent of dose was excreted in the 24-h urine as benazeprilat. The drug disposition did not change during repeated oral dosing and only small accumulation of the metabolite occurred. The accumulation ratio was 1.20 for AUC and 1.24 for urinary excretion. The effective half-life for accumulation was estimated at about 10-11 h. The comparison with other ACE inhibitors showed similarities but also marked differences with respect to the drug kinetics and excretion.     

Pharmacokinetics of primaquine in man: identification of the carboxylic acid derivative as a major plasma metabolite

A method is described for the simultaneous determination of the carboxylic acid and N-acetyl-derivatives of primaquine, in plasma and urine. After oral administration of 45 mg primaquine, to five healthy volunteers, absorption was rapid, with peak primaquine levels of 153.3 +/- 23.5 ng/ml at 3 +/- 1 h, followed by an elimination half-life of 7.1 +/- 1.6 h, systemic clearance of 21.1 +/- 7.1 l/h, volume of distribution of 205 +/- 371 and cumulative urinary excretion of 1.3 +/- 0.9% of the dose. Primaquine underwent rapid conversion to the carboxylic acid metabolite of primaquine, which achieved peak levels of 1427 +/- 307 ng/ml at 7 +/- 4 h. Levels of this metabolite were sustained in excess of 1000 ng/ml for the 24 h study period, and no carboxyprimaquine was recovered in urine. N-acetyl primaquine was not detected in plasma or urine. Following [14C]-primaquine administration to one subject, plasma radioactivity levels rapidly exceeded primaquine concentrations. Plasma radioactivity was accounted for mainly as carboxyprimaquine . Though 64% of the dose was recovered over 143 h, as [14C]-radioactivity in urine, only 3.6% was due to primaquine. As neither carboxyprimaquine nor N- acetylprimaquine were detected in urine, the remaining radioactivity was due to unidentified metabolites.     

The influence of liver dysfunction on the pharmacokinetics of carprofen

The pharmacokinetics of the investigational agent carprofen were examined in 12 patients with liver dysfunction (hepatic cirrhosis) and in six normal volunteers following single 100-mg oral administration of carprofen. In addition, three patients with acute hepatitis received a single 100-mg dose during the acute phase of the disease, and two of these patients received the same dose after they had convalesced. The pharmacokinetic parameters and urinary excretion data did not differ significantly (P greater than 0.05) between patients with hepatic cirrhosis and healthy volunteers. The mean +/- SD area under plasma concentration-time curve and apparent oral plasma clearance values were 57.8 +/- 11.7 micrograms X h/mL and 30.0 +/- 6.3 mL/min, respectively, in patients and 52.4 +/- 11.3 micrograms X h/mL and 33.1 +/- 7.2 mL/min in normals. The respective harmonic mean elimination half-lives were 10.5 and 9.4 hours. The 0-24 hour urinary recovery of intact drug and the glucuronide conjugate were 7.0 +/- 4.9% and 28.9 +/- 11.0%, respectively, in patients compared to 5.5 +/- 7.1% and 20.1 +/- 12.3% in normal subjects. The results of this study showed that liver dysfunction (hepatic cirrhosis) had no effect on the pharmacokinetic profile of carprofen. In the two patients with acute hepatitis who completed the study, the results suggest that the apparent oral clearance of carprofen may increase during the acute phase of the disease.