Pharmacokinetics and tissue distribution of ketanserin in rat, rabbit and dog

The plasma kinetics and tissue distribution of ketanserin [+)-3-[2-[4-(4-fluorobenzoyl)-1-piperidinyl]ethyl]-2,4(1H,3H)- quinazolinedione, R 41 468) were studied in the rat, rabbit and dog. The studies were performed utilizing 3H- and 14C-labelled ketanserin and appropriate techniques to measure levels of radioactivity, unchanged drug and a major metabolite ketanserin-ol in plasma and tissues. Following intravenous administration to male rats and dogs (10 mg/kg), plasma levels could be described by a two-compartment model. The plasma clearance (C1) averaged 3.8 and 19.2 ml/min/kg and the volume of distribution (Vdss) 0.67 and 4.7 l/kg in male rats and in dogs, respectively. Following oral administration (10-40 mg/kg), ketanserin was rapidly and completely absorbed in all species studied. The absolute bioavailability of oral ketanserin was more than 80% in both rats and dogs. Due to the high clearance of the metabolites in rats, ketanserin was the main component of the plasma radioactivity. In dogs, the fraction of the metabolite ketanserin-ol was more pronounced than that of ketanserin. The apparent elimination half-life of ketanserin was 1.5 h in rabbits, 2-5 h in rats and 3-15 in dogs. The pharmacokinetics of ketanserin were dose-related after single and chronic intravenous and oral dosing. Distribution studies in rats after intravenous and oral administration (10 mg/kg) demonstrated an almost immediate equilibrium between plasma and tissues, resulting in slightly higher tissue than plasma concentrations in the well perfused tissues, and similar or slightly lower levels in the remaining tissues. Ketanserin was the main component of tissue radioactivity. The drug crossed the blood-brain barrier only to a slight extent, brain levels of the unchanged drug being similar to the free fraction in plasma. Ketanserin disappeared from tissues with a similar half-life to that in plasma. On repeated dosing, a small fraction of metabolites was more slowly eliminated. The excretion of the urinary and faecal metabolites after repeated dosing was very similar to that after a single dose. Placental transfer of ketanserin in the rat was limited. On average 0.3% of the maternal radioactive dose, preferentially metabolites, was recovered from the combined foetuses. In dogs orally treated with doses of up to 40 mg/kg/d for 12 months, no undue accumulation or retention of ketanserin or ketanserin-ol was found in any tissue. In lactating dogs orally dosed at 10 mg/kg, preferentially metabolites were excreted in the milk. Concentrations of ketanserin and ketanserin-ol in the milk were respectively 2 and 4 times higher than plasma levels.     

Metabolism and excretion of imrecoxib in rat

The metabolism and excretion of imrecoxib, a novel and moderately selective cyclooxygenase-II inhibitor, were investigated in rat. The structures of metabolites were identified by mass spectrometry (MSn) and nuclear magnetic resonance. Metabolic profiles of imrecoxib in urine, bile and faeces were obtained by HPLC and LC/MSn, and cumulative excretion was determined by LC/MSn. Imrecoxib was extensively metabolized in rat after intravenous administration, with less than 2% of the dose excreted as parent drug in either urine or faeces. The major metabolic pathway was that the 4'-methyl group of imrecoxib was first oxidized to the 4'-hydroxymethyl metabolite (M4), followed by additional oxidation to 4'-carboxylic acid metabolite (M2). The dihydroxylated metabolite, 4'-hydroxymethyl-5-hydroxyl imrecoxib (M3), was further oxidized to 4'-hydroxymethyl-5-carbonyl metabolite (M5), and glucuronide conjugates of M2-4 were formed. After intravenous (5 mg kg-1) administration, the majority of the dose was recovered in the faeces. The dose was primarily excreted as the carboxylic acid metabolite in addition to the 4'-hydroxymethyl metabolite. The carboxylic acid metabolite was mainly excreted in faeces, while the 4'-hydroxymethyl metabolite was mainly excreted in urine.     

Excretion and metabolism of flunarizine in rats and dogs

The excretion and metabolism of (E)-1-[bis(4-fluorophenyl)methyl]-4-(3-phenyl-2-propenyl)piperazine dihydrochloride (flunarizine hydrochloride, R 14 950, Sibelium) were studied after single oral doses in rats and dogs, using tritium-labelled as well as 14C-labelled drug. Flunarizine was well absorbed in both species. The mass balance for the unchanged drug and its major metabolites in urine, bile and faeces, as estimated with radio-HPLC, ALLOWED an explanation of the differences observed for the excretion pattern of the radioactivity in flunarizine-14C and flunarizine-3H dosed rats, and in male and female rats. Main metabolic pathway in male rats was the oxidative N-dealkylation resulting in bis(4-fluorophenyl)methanol and a number of complementary metabolites of the cinnamylpiperazine moiety, of which hippuric acid was the main one. In female rats and male dogs, however, hydroxy-flunarizine was the main metabolite, resulting from the aromatic hydroxylation of the phenyl ring of the cinnamyl moiety. Enterohepatic circulation of bis(4-fluorophenyl)methanol and hydroxy-flunarizine was proved by "donor-acceptor" coupling in rats; in bile and urine, these two metabolites were present mainly as glucuronides. The glucuronide of hydroxy-flunarizine was also the main plasma metabolite in dogs.     

Metabolism of the dyestuff intermediate 2,4-diaminoanisole in the rat.

1. 2,4-Diamino[ring-U-14C]anisole.2HCl administered intraperitoneally to rats is excreted chiefly via the urine (79 and 85% of the dose in 24 and 48 h, respectively). The isotope in the faeces was 2.1 and 8.9% of the dose at 24 and 48 h. 2. The major metabolic pathway was acetylation of the amine groups(s), resulting in 4-acetylamino-2-aminoanisole and 2,4-diacetylaminoanisole. 3. Oxidate pathways yielded 2,4-diacetylaminophenol (O-demethylation), 5-hydroxy-2,4-diacetylaminoanisole (ring hydroxylation), and 2-methoxy-5-(glycol-amido)acetanilide or its isomer (omega-oxidation). 4. These major metabolites were excreted in the urine both as free and glucuronic acid conjugates.     

Evaluation of the absorption, excretion and metabolism of [14C] etoperidone in man.

1. The absorption, excretion and metabolism of 2-[3-[4-(3-chlorophenyl)-1-piperazinyl]propyl]-4,5-diethyl-2,4-dihydro-3H-1,2,4- triazole-3-one hydrochloride (etoperidone HCl) was investigated in six healthy men. Subjects were tasted overnight before receiving a single oral dose of a 100 mg solution [14C] etoperidone HCl. 2. Plasma (0-48 h), urine (0-120 h) and faecal (0-120 h) samples were collected. The terminal half-life of the total radioactivity from plasma was 21.7 +/- 2.8h with an apparent clearance of 1.01 +/- 0.08 ml min(-1). Recoveries of total radioactivity in urine and faeces were 78.8 +/- 3.6% and 9.6 +/- 4.1% of the dose, respectively. 3. Etoperidone and 21 metabolites were isolated and identified in the plasma, urine and faecal extracts. Unchanged etoperidone accounted for <0.01% of the dose in all excreta samples. Nine metabolites were identified in the plasma extracts and 21 urinary metabolites were identified. Seven faecal metabolites were identified. 4. Five proposed pathways were used to describe the formation of the metabolites: alkyl oxidation, piperazinyl oxidation, N-dealkylation, phenyl hydroxylation and conjugation. Alkyl oxidation of etoperidone resulted in the formation of 2-[3-[4-(3-chlorophenyl)-1-piperazinyl]propyl]-4-ethyl-2,4-dihydro-5- (1-hydroxyethyl)-3H-1,2,4-triazole-3-one. Piperazinyl oxidation of this metabolite leads to the formation of its N-oxide. N-dealkylation of the piperazinyl group led to the formation of 1-(3-chlorophenyl) piperazine and triazole propionic acid. Phenyl hydroxylation led to three important metabolites in the urine and faeces.     

Evaluation of the absorption,excretion and metabolism of [14 C] etoperidone in man

1. The absorption, excretion and metabolism of 2-{3-[4-(3-chlorophenyl)-1-piperazinyl]propyl}-4,5-diethyl-2,4-dihydro-3H-1,2,4 hydrochloride (etoperidone HCl) was investigated in six healthy men. Subjects were fasted overnight before receiving a single oral dose of a 100mg solution [14C] etoperidone HCl. 2. Plasma (0-48h), urine (0-120h) and faecal (0-120h) samples were collected. The terminal half-life of the total radioactivity from plasma was 21.7 ± 2.8?h with an apparent clearance of 1.01 ± 0.08 ml min-1. Recoveries of total radioactivity in urine and faeces were 78.8 ± 3.6% and 9.6 ± 4.1% of the dose, respectively. 3. Etoperidone and 21 metabolites were isolated and identified in the plasma, urine and faecal extracts. Unchanged etoperidone accounted for <0.01% of the dose in all excreta samples. Nine metabolites were identified in the plasma extracts and 21 urinary metabolites were identified. Seven faecal metabolites were identified. 4. Five proposed pathways were used to describe the formation of the metabolites: alkyl oxidation, piperazinyl oxidation, N -dealkylation, phenyl hydroxylation and conjugation. Alkyl oxidation of etoperidone resulted in the formation of 2-{3-[4-(3- chlorophenyl)-1-piperazinyl]propyl}-4-ethyl-2,4-dihydro-5-(1-hydroxyethyl)-3H-1 triazole-3-one. Piperazinyl oxidation of this metabolite leads to the formation of its N -oxide. N -dealkylation of the piperazinyl group led to the formation of 1-(3-chlorophenyl) piperazine and triazole propionic acid. Phenyl hydroxylation led to three important metabolites in the urine and faeces.     

Metabolism of Femoxetine

Abstract: The metabolism of femoxetine, a serotonin uptake inhibitor, has been investigated in rats, dogs, monkeys, and human subjects using two ¹⁴C-femoxetine compounds with labelling in different positions. The metabolic pathways were oxidation (and glucuronidation) and demethylation, both reactions most probably taking place in the liver. Nearly all femoxetine was metabolised, and the same metabolites were found in urine from all four species. Only a small percentage of the radioactivity excreted in the urine was not identified. Rat and dog excreted more N-oxide than monkey and man, while most of the radioactivity (60–100%) in these two species was excreted as two hydroxy metabolites. The metabolic pattern in monkey and man was very similar. About 50% was excreted in these two species as one metabolite, formed by demethylation of a methoxy group. A demethylation of a N-CH₃ group formed an active metabolite, norfemoxetine. The excretion of this metabolite in urine from man varied from 0 to 18% of the dose between individuals. Most of the radioactivity was excreted with the faeces in rat and dog, while monkey and man excreted most of the radioactivity in urine. This difference in excretion route might be explained by the difference in the metabolic pattern. No dose dependency was observed in any of the three animal species investigated.     

Studies on the metabolism of aristolochic acids I and II

1. After oral administration of aristolochic acid I (AAI) and aristolochic acid II (AAII) to rats, the following metabolites were isolated from the urine and their structures elucidated: aristolactam I, aristolactam Ia, aristolochic acid Ia, aristolic acid I and 3, 4-methylenedioxy-8-hydroxy-1-phenanthrenecarboxylic acid (metabolites of AAI); or aristolactam Ia, aristolactam II and 3,4-methylenedioxy-1-phenanthrenecarboxylic acid (metabolites of AAII). A further metabolite of AAII having a lactam structure has not yet been isolated in pure form.

2. The metabolic pathways have been elucidated by administration of various metabolites.

3. The principal metabolite of AAI in rats was aristolactam Ia; 46% of the dose was excreted in the urine in form of this metabolite and 37% in the faeces. The other substances were minor metabolites. Those metabolites of AAII whose structures have been elucidated were minor metabolites; the largest proportion consisted of aristolactam II, which accounted for 4.6% in the urine and 8.9% in the faeces.

4. The mouse was the only animal which had the same metabolite patterns of AAI and AAII as those found in the rat. Not all the metabolites listed above were found in urine from guinea pigs, rabbits, dogs and man.     

Excretion and biotransformation of cisapride in dogs and humans after oral administration

The excretion and biotransformation of cisapride, a novel gastrokinetic drug, were studied after a single po dose of [14C]cisapride in dogs and humans. The excretion of radioactivity amounted to 97% within 4 days after a 1 mg/kg dose in dogs (72% in feces and 25% in urine). After a 10-mg dose in humans, 44% was excreted in the 0-24-hr urine and 37% in the 0-35-hr feces; excretion was complete within 4 days. Excretion of the parent drug was greater in dogs (0.4-1.3% of the dose in urine, 23% in feces) than in humans (0.2% in urine, 4-6% in feces). This was due, at least in part, to a larger proportion of amine glucuronidation and sulfation in dogs. N-Deal-kylation at the piperidine nitrogen resulting in the main urinary metabolite, norcisapride, and aromatic hydroxylation of the 4-fluorophenyl ring were major metabolic pathways in both species. Norcisapride excretion accounted for 14% of the dose in dogs and 41-45% in humans. Minor metabolic pathways were O-dealkylation at the 4-fluorophenoxy group and piperidine oxidation. Peak plasma levels and AUC values of norcisapride in humans were 8-9 times lower than those of cisapride. Apart from more amine conjugation in dogs, the biotransformation of cisapride was similar in dogs and humans.     

Studies on the metabolism of aristolochic acids I and II

1. After oral administration of aristolochic acid I (AAI) and aristolochic acid II (AAII) to rats, the following metabolites were isolated from the urine and their structures elucidated: aristolactam I, aristolactam Ia, aristolochic acid Ia, aristolic acid I and 3,4-methylenedioxy-8-hydroxy-1-phenanthrenecarboxylic acid (metabolites of AAI); or aristolactam Ia, aristolactam II and 3,4-methylenedioxy-1-phenanthrenecarboxylic acid (metabolites of AAII). A further metabolite of AAII having a lactam structure has not yet been isolated in pure form. 2. The metabolic pathways have been elucidated by administration of various metabolites. 3. The principal metabolite of AAI in rats was aristolactam Ia; 46% of the dose was excreted in the urine in form of this metabolite and 37% in the faeces. The other substances were minor metabolites. Those metabolites of AAII whose structures have been elucidated were minor metabolites; the largest proportion consisted of aristolactam II, which accounted for 4.6% in the urine and 8.9% in the faeces. 4. The mouse was the only animal which had the same metabolite patterns of AAI and AAII as those found in the rat. Not all the metabolites listed above were found in urine from guinea pigs, rabbits, dogs and man.     

Metabolism of the calcium antagonist gallopamil in man

The metabolism of gallopamil (5-[(3,4-dimethoxyphenyl)methylamino]-2-(3,4,5-trimethoxyphenyl) -2- isopropylvaleronitrile hydrochloride, Procorum, G) was studied after single administration (2 mg i.v., 50 mg p.o.) of unlabelled and labelled G (14G, 2H). TLC, HPLC, GLC, MS and RIA were used for assessment of G and its metabolites in plasma, urine and faeces. G clearance is almost completely metabolic, with only minimal excretion of unchanged drug. Metabolites represent most of the plasma radioactivity after p.o. administration. They are formed by N-dealkylation and O-demethylation with subsequent N-formylation, or glucuronidation, respectively. Compound A, derived by loss of the 3,4-dimethoxyphenethyl moiety of G is the main metabolite in plasma and urine (about 20% of the dose). This metabolite is accompanied by its N-formyl derivative (C), by the N-demethylated compound (H) and the acid (F), formed by oxidative deamination of A. Only 3 unconjugated monphenoles from several O-demthylated products showed distinct plasma levels which were nevertheless lower than metabolite A. These metabolites had no relevance to the pharmacodynamic action. Conjugated monophenolic and diphenolic products represented the major part in plasma and were excreted predominantly via the bile: they represented almost the whole faecal metabolite fraction. Less than 1% of the dose was recovered unchanged in the urine. About 50% of the dose is excreted by urine and 40% by faeces.     

Species-differences in disposition and reductive metabolism of methoxymorpholinodoxorubicin (PNU 152243), a new potential anticancer agent.

Plasma pharmacokinetics, excretion balance and urinary metabolites of methoxymorpholino doxorubicin (MMDX) were investigated in male and female rats and in female dogs after i.v. administration of the(14)C-labelled drug. The mean total recovery of radioactivity in 96 h (urine plus faeces) was approximately 74 and 60% dose in male and female rats, respectively, while in female dogs approximately 72% dose was recovered in 336 h. Most of the radioactivity was present in faeces, with the urinary elimination accounting for only 3-4% dose in rats and dogs. These data suggest that biliary excretion is an important route of elimination of MMDX and/or its metabolites in both species. No differences were observed in the urinary metabolic profile of male and female rats. Two main peaks were present in radiochromatograms of urine from rats and dogs, i.e. MMDX and its 13-dihydro metabolite (MMDX-ol), accounting for approximately 25 and 20% of total radioactivity in 0-24-h urine in rats and 30 and 36% in dogs. The MMDX-ol/MMDX ratio in dog urine was higher than that observed in rat urine. No aglycones were detected in the urine samples from either species. In the rat, the plasma concentration-time profile suggested that the disposition of MMDX, MMDX-ol and total radioactivity is not sex-dependent. MMDX was the major species present in the systemic circulation; its AUC (0-96 h) accounted for 70% of total plasma radioactivity with the sum of AUC (MMDX) plus AUC (MMDX-ol) accounting for 77% of total radioactivity. In the dog, the sum of AUC (MMDX) plus AUC (MMDX-ol) amounted to 8% of radioactivity AUC(0-t(z) indicating that an important proportion of other(s) unknown metabolite(s) is present in dog plasma. Plasma levels of MMDX-ol in the rat were approximately 10-fold lower than those of the parent compound, whereas they were three times higher than those of MMDX in the dog. These data show that the reduction of the 13-keto group of MMDX is species-dependent, and occurs preferentially in the dog compared to the rat.     

Excretion and metabolism of lorcainide in rats, dogs and man

After p.o. or i.v. administration of 3H-lorcainide, excretion of the radioactivity was almost complete within four days. In rats and dogs, about 35% of the dose was excreted in the urine and about 60% in the faeces. However, in humans, 62% was excreted in the urine and 35% in the faeces. In rats, about 70% of the orally administered radioactivity was excreted in the bile within 24 hours. Enterohepatic circulation was proven by "donor-acceptor" coupling in rats. Lorcainide was extensively metabolized. Urinary and faecal metabolites were isolated by extraction and high pressure liquid chromatography (HPLC), and characterized by chromatographic comparison with reference compounds, by mass spectrometry, and NMR. The mass balance for unchanged lorcainide and its major metabolites (determined by radio-HPLC) was very similar in the urine and faeces. Only minor quantitative differences were observed between intravenously and orally dosed animals, and between male and female rats. Major biotransformation pathways in the three species were: hydroxylation, O-methylation and glucuronidation. 4-Hydroxy-3-methoxy-lorcainide was the main metabolite. alpha-Oxidation resulting in alpha, 4-dihydroxy-3-methoxy-lorcainide, was observed in dogs only. Minor pathways were: oxidative N-dealkylation and amide hydrolysis. A remarkable 5-hydroxy-3,4-dimethoxy-metabolite was identified unambiguously in the three species.     

Disposition of 2,4-dinitroaniline in the male F-344 rat

The disposition and metabolism of 2,4-dinitroaniline was studied in male F-344 rats following oral and i.v. administration. Gastrointestinal absorption was near complete and was not affected by dose (10-90 mumol/kg). Following either oral or i.v. administration, dinitroaniline was rapidly distributed throughout the tissues and showed no marked affinity for any particular tissue. 14C-dinitroaniline was readily cleared by metabolism to at least nine metabolites; radioactivity was excreted primarily in urine (70% dose) and to a lesser extent in faeces (25-30% dose). Clearance of radioactivity from the body was near complete in 3 days. As the whole-body half-life of dinitroaniline derived radioactivity in the rat was less than 3 h and there was no evidence for saturation of any mechanism of absorption, distribution, metabolism or excretion in the dose range studied, 2,4-dinitroaniline appears to have little potential for bioaccumulation in animal tissues. Analysis of urine and bile detected nine metabolites of 2,4-dinitroaniline. The major metabolite was excreted in urine as a sulphate conjugate and in bile as a glucuronide. This metabolite was characterized by combined h.p.l.c./mass spectrometry as 2,4-dinitrophenylhydroxylamine.     

Biotransformation of BOF-4272, a sulfoxide-containing drug, in the cynomolgus monkey.

BOF-4272, (+/-)-8-(3-methoxy-4-phenylsulfinylphenyl) pyrazolo[1,5-a]-1,3,5-triazine-4(1H)-one), is a new drug intended for the treatment of hyperuricemia. This report describes the pharmacokinetics and detailed metabolic pathways of BOF-4272 in the cynomolgus monkey, which were investigated using the metabolites found in plasma, urine, and faeces after intravenous and oral administration. M-4 was the main metabolite in plasma after intravenous administration. M-3 and M-4 were the main metabolites in plasma after oral administration. The Cmax and AUC(0-t) of M-4 were the highest of all the metabolites after intravenous administration. The Cmax and AUC(0-t) of M-3 were the highest of all the metabolites, and those of M-4 were the second highest, after oral administration. M-4 and M-3 were the main metabolites detected in urine and faeces, respectively, after intravenous administration, with M-4 and M-3 at 47.2% in urine and 19.1% in faeces, respectively, within 120 h after administration. M-4 was the only metabolite detected in urine after oral administration, at about 5% within 120 h after administration. M-3 was detected in faeces at 17.0% within 120 h after oral administration. These results suggest that, in the cynomolgus monkey, BOF-4272 is rapidly biotransformed to a main metabolite (M-4, a sulphoxide-containing metabolite of BOF-4272) and that M-4 is mainly excreted in urine and possibly also in bile, with subsequent conversion to M-3 by the intestinal flora. It is expected that the biotransformation of BOF-4272 would be similar in healthy human volunteers.     

Excretion and biotransformation of alfentanil and sufentanil in rats and dogs

The excretion and biotransformation of alfentanil (ALF) and sufentanil (SUF), two recent analogues of the synthetic opioid fentanyl, were studied after single iv administration of the tritium-labeled drugs in male rats and dogs. The drugs were almost completely metabolized in the two species, which resulted in a large number of metabolites. The excretion of the metabolites was rapid and exceeded 95% within 4 days, except for that of ALF metabolites in dogs (about 85%). For ALF, excretion of the radioactivity with the urine (73% in rats, about 76% in dogs) exceeded that with the feces. For SUF, excretion of the radioactivity with the urine amounted to 38 and 60% and that with the feces to 62 and 40%, in rats and dogs, respectively. Bile-cannulated rats excreted 68% with the bile within 24 hr after SUF dosing, and about 22% of this biliary radioactivity was subjected to enterohepatic circulation. After an ALF dose, the biliary excretion amounted to 24%, and the enterohepatic circulation was minimal. The main metabolic pathways of the two drugs were the oxidative N-dealkylation at the piperidine nitrogen and at the amide nitrogen, oxidative O-demethylation, aromatic hydroxylation, and the formation of ether glucuronides. N-[4-(Hydroxymethyl)-4-piperidinyl]-N-phenylpropanamide (M6) was the main metabolite of both ALF and SUF in rats. In dogs, the glucuronide of N-(4-hydroxyphenyl)propanamide (M5) was the main metabolite of ALF. After SUF dosing in dogs, N-[4-(methoxymethyl)-4-piperidinyl]-N-phenylpropanamide was more abundant than M5.     

Metabolism of 2,4-diamino-6-(2,5-dichlorophenyl)-s-triazine maleate in rats, guinea pigs, dogs and monkeys

The metabolism of 2,4-diamino-6-(2,5-dichlorophenyl)-s-triazine maleate (MN-1695) was studied in rats, guinea pigs, dogs and monkeys. MN-1695 was metabolized to more than 8 metabolites after oral administration in a dose of 3.1 mg/kg in rats. These metabolites were isolated from the urine and characterized by cochromatography with reference compounds, mass spectrometry and other instrumental analysis. The main metabolite in the urine was MN-1695 X m-OH, which was excreted as a conjugate, in rats and guinea pigs, and MN-1695 X N-oxide in dogs. In monkeys, MN-1695 X m-OH (free and conjugate) and MN-1695 X N-oxide predominated in the urine, although MN-1695 was not extensively metabolized. In rats, over 90% of the radioactivity excreted into the bile consisted of the polar metabolites. The major metabolic pathways of MN-1695 found in various animal species involved the hydroxylation at the positions of 3 and 4 of the aromatic ring and the N-oxidation at the position of 3 of the s-triazine ring. In addition, the sulfur-containing metabolites were detected in all species examined.     

Excretion, metabolism, and pharmacokinetics of CP-945,598, a selective cannabinoid receptor antagonist, in rats, mice, and dogs

1-(8-(2-Chlorophenyl)-9-(4-chlorophenyl)-9H-purin-6-yl)-4-(ethylamino)piperidine-4-carboxamide (CP-945,598) is an orally active antagonist of the cannabinoid CB-1 receptor that progressed into phase 3 human clinical trials for the treatment of obesity. In this study, we investigated the metabolic fate and disposition of CP-945,598 in rats, Tg-RasH2 mice, and dogs after oral administration of a single dose of [(14)C]CP-945,598. Total mean recoveries of the radioactive dose were 97.7, 97.8, and 99.3% from mice, rats, and dogs, respectively. The major route of excretion in all three species was via the feces, but on the basis of separate studies in bile duct-cannulated rats and dogs, this probably reflects excretion in bile rather than incomplete absorption. CP-945,598 underwent extensive metabolism in all three species, because no unchanged parent compound was detected in the urine across species. The primary metabolic pathway of CP-945,598 involved N-deethylation to form an N-desethyl metabolite (M1). M1 was subsequently metabolized by amide hydrolysis, oxidation, and ribose conjugation to numerous novel and unusual metabolites. The major circulating and excretory metabolites were species-dependent; however, several common metabolites were observed in more than one species. In addition to parent compound, M1, M3, M4, and M5 in rats, M1, M3, and M4 in mice, and M1 and M2 in dogs were identified as the major circulating metabolites. Gender-related differences were also apparent in the quantitative and qualitative nature of the metabolites in rats. An unprecedented metabolite, M4, formed by deamidation of M1 or M3 (N-hydroxy-M1), but not by decarboxylation of M2, was identified in all species. M4 was nonenzymatically converted to M5.     

Metabolism and excretion of RWJ-333369 [1,2-ethanediol, 1-(2-chlorophenyl)-, 2-carbamate, (S)-] in mice, rats, rabbits, and dogs.

The in vivo metabolism and excretion of RWJ-333369 [1,2-ethanediol, 1-(2-chlorophenyl)-, 2-carbamate, (S)-], a novel neuromodulator, were investigated in mice, rats, rabbits, and dogs after oral administration of (14)C-RWJ-333369. Plasma, urine, and feces samples were collected, assayed for radioactivity, and profiled for metabolites. In almost all species, the administered radioactive dose was predominantly excreted in urine (>85%) with less than 10% in feces. Excretion of radioactivity was rapid and nearly complete at 96 h after dosing in all species. Unchanged drug excreted in urine was minimal (<2.3% of the administered dose) in all species. The primary metabolic pathways were O-glucuronidation (rabbit > mouse > dog > rat) of RWJ-333369 and hydrolysis of the carbamate ester followed by oxidation to 2-chloromandelic acid. The latter metabolite was subsequently metabolized in parallel to 2-chlorophenylglycine and 2-chlorobenzoic acid (combined hydrolytic and oxidative pathways: rat > dog > mouse > rabbit). Other metabolic pathways present in all species included chiral inversion in combination with O-glucuronidation and sulfate conjugation (directly and/or following hydroxylation of RWJ-333369). Species-specific pathways, including N-acetylation of 2-chlorophenylglycine (mice, rats, and dogs) and arene oxidation followed by glutathione conjugation of RWJ-333369 (mice and rats), were more predominant in rodents than in other species. Consistent with human metabolism, multiple metabolic pathways and renal excretion were mainly involved in the elimination of RWJ-333369 and its metabolites in animal species. Unchanged drug was the major plasma circulating drug-related substance in the preclinical species and humans.     

Metabolism of Beclamide after a Single Oral Dose in Man: Quantitative Studies

A simple reverse phase HPLC assay is described for the determination of the anticonvulsant compound, beclamide and its 3- and 4-hydroxyphenyl metabolites in urine. Following oral administration of 1 g beclamide to a panel of healthy volunteers, less than 0.4% of the dose was excreted unchanged in the 24-h urine and unconjugated 3- and 4-hydroxyphenyl metabolites were not detected. Based on examination of the urine after incubation with β-glucuronidase and aryl sulphatase, it was found that these hydroxyl metabolites were excreted as both glucuronide and sulphate conjugates. For each metabolite the glucuronide was the major excretory product (approximately 10: 1). The 24-h excretion of the combined conjugated metabolites was 7% (for the 3-hydroxy metabolite) and 24% (for the 4-hydroxy metabolite) of the dose. Approximately 22% of the administered dose of beclamide was excreted as hippuric acid. In view of the simplicity of assay, beclamide may be a useful tool substance with which to examine factors influencing the xenobiotic metabolic pathways of benzene ring hydroxylation and glucuronide and sulphate conjugation in man.