Metabolic disposition of isoxicam in man, monkey, dog, and rat

Isoxicam a new nonsteroidal antiinflammatory agent was radiolabeled with 14C at the 3-position of the benzothiazine nucleus. It was well absorbed following peroral administration to man, monkey, dog, and rat, reaching peak plasma concentrations in 4-8 hr. Over 90% of the plasma radioactivity was due to unchanged drug. Plasma elimination half-lives were 22-45 hr in man and 49-53 hr in dogs and 20-35 hr in rats and monkeys. Isoxicam was distributed to most tissues in rats, but the tissue-plasma ratio did not exceed unity, indicating a small volume of distribution. It was extensively metabolized with only a few per cent of the dose appearing as unchanged drug in the urine. The principal urinary metabolite in man was formed by hydroxylation of the methyl group on the isoxozole ring and accounted for 30-35% of an isoxicam dose. In the rat, oxoacetic acid, the major urinary metabolite, was formed by opening of the benzothiazine ring followed by hydrolytic cleavage of the C-3 to N-2 bond. In addition to the hydroxymethyl and oxoacetic acid, two unknown metabolites, accounting for only a small percentage of dose, were detected in the urine of all four species. Urinary excretion of 14C activity accounted for about 60% of a dose in man and rats, 31% in monkeys, and 17% in dogs. These results indicate that there is only a quantitative rather than a qualitative species difference in the metabolic disposition of isoxicam.     

Excretion and metabolism of recainam, a new anti-arrhythmic drug, in laboratory animals and humans

The metabolic disposition of recainam, an antiarrhythmic drug, was compared in mice, rats, dogs, rhesus monkeys, and humans. Following oral administration of [14C]recainam-HCl, radioactivity was excreted predominantly in the urine of all species except the rat. Metabolite profiles were determined in excreta by HPLC comparisons with synthetic standards. In rodents and rhesus monkeys, urinary excretion of unchanged recainam accounted for 23-36% of the iv dose and 3-7% of the oral dose. Aside from quantitative differences attributable to presystemic biotransformation, metabolite profiles were qualitatively similar following oral or iv administration to rodents and rhesus monkeys. Recainam was extensively metabolized in all species except humans. In human subjects, 84% of the urinary radioactivity corresponded to parent drug. The major metabolites in mouse and rat urine and rat feces were m- and p-hydroxyrecainam. Desisopropylrecainam and dimethylphenylaminocarboxylamino propionic acid were the predominant metabolites in dog and rhesus monkey urine. Small amounts of desisopropylrecainam and p-hydroxyrecainam were excreted in human urine. Selective enzymatic hydrolysis revealed that the hydroxylated metabolites were conjugated to varying degrees among species. Conjugated metabolites were not present in rat urine or feces, while conjugates were detected in mouse, dog, and monkey urine. Structural confirmation of the dog urinary metabolites was accomplished by mass spectral analysis. The low extent of metabolism of recainam in humans suggests that there will not be wide variations between dose and plasma concentrations.     

Metabolism of the neuroleptic agent zetidoline in the rat and the dog

The metabolism of zetidoline, a new neuroleptic, in the rat and the dog has been studied. From the urine of rats and dogs given 5 mg/kg of [2-14C] zetidoline orally, unchanged drug and five metabolites were isolated and the structures of four of them assigned by physicochemical analysis. They are: metabolite B, 4'-hydroxy-3'-chlorophenyl zetidoline; metabolite D, zetidoline without the aryl group; metabolite E, the 6'-hydroxy-4'-beta-D-glucuronide of metabolite B, and metabolite F, the 4'-beta-D-glucuronide of metabolite B. The plasma levels of zetidoline and its metabolites after iv administration show that the drug is rapidly excreted and/or metabolized in both animal species. The plasma radioactivity in the dog consists mainly of the pharmacologically active (neuroleptic) metabolite B, whereas in the rat it consists of the more polar metabolites. After oral administration, elimination in both species occurs mostly via the kidneys. In the dog, within a 24-hr period, 6.2 +/- 0.4% of the dose is accounted for as unchanged zetidoline, 7.6 +/- 0.5% as metabolite B, 10.1 +/- 0.7% as the unidentified metabolite C, and 21.4 +/- 1.1% as metabolite F. In the rat, over the same period, zetidoline is present in traces, metabolite B accounts for 6.9 +/- 0.3% of the dose, metabolite D for 6.6 +/- 0.9%, metabolite E for 15.2 +/- 1.4%, and metabolite F for 31.7 +/- 2.2%.     

The metabolic disposition of (S)-2-(3-tert-butylamino-2-hydroxypropoxy)-3-cyanopyridine in rats, dogs, and humans

Studies of the metabolic disposition of (S)-2-(3-tert-butylamino-2-hydroxypropoxy)-3-[14C]cyanopyridine (I) have been performed in humans, dogs, and spontaneously hypertensive rats. After an iv injection of I (5 mg/kg), a substantial fraction of the radioactivity was excreted in the feces of rats (32%) and dogs (31%). After oral administration of I (5 mg/kg) the urinary recoveries of radioactivity for rat and dog were 19% and 53%, respectively, and represented a minimum value for absorption because of biliary excretion of radioactivity. In man, bililary excretion of I appeared to be of minor significance because four male subjects, after receiving 6 mg of I p.o., excreted 76% and 9% of the dose of radioactivity in the urine and feces, respectively. Unchanged I represented 58% of the radioactivity excreted in human urine. The half-life for renal elimination of I was determined to be 4.0 +/- 0.9 /hr. In contrast, unchanged I represented 7% and 1% of excreted radioactivity in rat and dog urine, respectively. A metabolite of I common to man, dog, and rat was identified as 5-hydroxy-I, which represented approximately 5% of the excreted radioactivity in all species. Minor metabolites of I in which the pyridine nucleus had undergone additional hydroxylation were present in dog urine along with an oxyacetic acid metabolite, also bearing a hydroxylated pyridine nucleus.     

Disposition and metabolic fate of atomoxetine hydrochloride: pharmacokinetics, metabolism, and excretion in the Fischer 344 rat and beagle dog.

These studies were designed to characterize the disposition and metabolism of atomoxetine hydrochloride [(-)-N-methyl-gamma-(2-methylphenoxy)benzenepropanamine hydrochloride; formerly know as tomoxetine hydrochloride] in Fischer 344 rats and beagle dogs. Atomoxetine was well absorbed from the gastrointestinal tract and cleared primarily by metabolism with the majority of its metabolites being excreted into the urine, 66% of the total dose in the rat and 48% in the dog. Fecal excretion, 32% of the total dose in the rat and 42% in the dog, appears to be due to biliary elimination and not due to unabsorbed dose. Nearly the entire dose was excreted within 24 h in both species. In the rat, low oral bioavailability was observed (F = 4%) compared with the high oral bioavailability in dog (F = 74%). These differences appear to be almost purely mediated by the efficient first-pass hepatic clearance of atomoxetine in rat. The biotransformation of atomoxetine was similar in the rat and dog, undergoing aromatic ring hydroxylation, benzylic oxidation (rat only), and N-demethylation. The primary oxidative metabolite of atomoxetine was 4-hydroxyatomoxetine, which was subsequently conjugated forming O-glucuronide and O-sulfate (dog only) metabolites. Although subtle differences were observed in the excretion and biotransformation of atomoxetine in rats and dogs, the primary difference observed between these species was the extent of first-pass metabolism and the degree of systemic exposure to atomoxetine and its metabolites.     

Identification of ibopamine metabolites in rat and dog urine

Metabolism of ibopamine (N-methyldopamine-O,O'-diisobutyryl ester) was studied in rats and dogs. The compound was well absorbed in both species when given orally. Most of the administered radiolabel (74-94%) was excreted within 24 hr in urine of both species. The major metabolite in rat urine was 4-glucuronylepinine (63% of the total administered dose). Minor metabolites identified were 4-O-glucuronyl-3-O-methylepinine, 3,4-dihydroxyphenylacetic acid (DOPAC), DOPAC-glucuronide, homovanillic acid (HVA), and HVA-glucuronide. Free epinine and epinine sulfate were detected in the range of less than 1% of the total administered dose. Metabolite patterns in dog urine were different from those of rat urine. The major metabolite was epinine-3-O-sulfate (62% of the total administered dose). Minor metabolites identified in dog urine were DOPAC-sulfate, HVA-sulfate, and free HVA. Free epinine was detected but in the range of less than 1% of the total administered dose. These results showed that ibopamine underwent extensive hydrolysis in vivo to epinine, which was subsequently conjugated and excreted as major metabolites in urine. In addition, side chain degradation of epinine led to minor metabolites, which were excreted in urine as free and conjugated forms. The route of conjugation of ibopamine metabolites is species dependent.     

Disposition and metabolism of almotriptan in rats, dogs and monkeys

Almotriptan is a new highly potent selective 5-HT1B/1D receptor agonist developed for the treatment of migraine, and the disposition of almotriptan in different animal species is now addressed in the current study. Almotriptan was well absorbed in rats (69.1%) and dogs (100%) following oral treatment. The absolute bioavailability was variable reflecting different degrees of absorption and first-pass metabolism (18.7-79.6%). The elimination half-life was short and ranged between 0.7 and 3 h. The main route of elimination of almotriptan was urine with 75.6% and 80.4% of the dose recovered over a 168-h period in rats and dogs, respectively. The gamma-aminobutyric acid metabolite formed by oxidation of the pyrrolidine ring was the main metabolite found in urine, faeces, bile, and plasma of rats and in monkey urine. By contrast, the unchanged drug, the indole acetic acid metabolite formed by oxidative deamination of the dimethylaminoethyl group, and the N-oxide metabolite were the main metabolites in dog.     

Pharmacokinetics, metabolism, and disposition of 6-chloro-2,3,4,5-tetrahydro-3-methyl-1H-3-benzazepine (SK&F 86466) in rats and dogs

The pharmacokinetics and metabolism of 6-chloro-2,3,4,5-tetrahydro-3-methyl-1H-3-benzazepine (SK&F 86466) have been studied in rats and dogs. Using radiolabeled SK&F 86466, it was shown that the compound was completely absorbed from the gastrointestinal tract following oral administration. Most of the administered radioactivity (approximately 80%) was excreted in urine with the remainder excreted in feces via the bile. Very little of the parent compound was excreted unchanged in the urine. The major urinary metabolite, accounting for about 55% of the dose in rat and 35% in dog, was the N-oxide. N-Demethylation also occurs in both species, and in the rat approximately 20% of the dose is metabolized by this route. The plasma concentration vs. time curves following iv administration were analyzed using a two-compartment open model. The distribution phase half-life was 0.24 hr in the rat and 0.37 hr in the dog. In both species the terminal half-life was approximately 2 hr. The volume of distribution at steady state in the rat was 12.1 liters/kg and in the dog was 8.2 liters/kg. About 55% of the drug in plasma was bound to protein in both species so that the volume of distribution of the free drug was 27 liters/kg in the rat and 19 liters/kg in the dog. The clearance of SK&F 86466 from blood was very high in both the dog (56 ml/min/kg) and the rat (191 ml/min/kg). Since less than 1% of the compound was excreted unchanged in urine, the clearance was almost entirely metabolic.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative metabolic disposition of oral doses of omeprazole in the dog, rat, and mouse

The metabolic disposition of [14C]omeprazole was studied in dogs, rats, and mice after the administration of pharmacologically active, single oral doses of drug in buffer solutions (pH 9). Averages of 38% (dogs), 43% (rats), and 55% (mice) of the radiolabeled doses were excreted in the urine in 72 hr. Most of the remaining dose was recovered in the feces. Omeprazole was extensively metabolized in all species studied and the metabolites were eliminated rapidly. No unchanged drug could be detected in the urine samples (less than 0.1% of dose). In each species at least 10 metabolites were detected in urine (pH 9) by gradient elution reverse phase HPLC. Based on liquid chromatographic retention data, the metabolic patterns were very complex and exhibited some quantitative differences between species. Bile was collected from rats and from chronic bile-fistulated dogs. Biliary excretion was a major route of elimination of omeprazole metabolites, and four polar metabolites were detected in the rat bile. The stability of omeprazole metabolites at varying pH values is discussed with reference to reductive metabolism of the parent compound.     

Disposition and metabolism of almotriptan in rats,dogs and monkeys

Almotriptan is a new highly potent selective 5-HT_1B/1D receptor agonist developed for the treatment of migraine, and the disposition of almotriptan in different animal species is now addressed in the current study. Almotriptan was well absorbed in rats (69.1%) and dogs (100%) following oral treatment. The absolute bioavailability was variable reflecting different degrees of absorption and first-pass metabolism (18.7–79.6%). The elimination half-life was short and ranged between 0.7 and 3?h. The main route of elimination of almotriptan was urine with 75.6% and 80.4% of the dose recovered over a 168-h period in rats and dogs, respectively. The γ-aminobutyric acid metabolite formed by oxidation of the pyrrolidine ring was the main metabolite found in urine, faeces, bile, and plasma of rats and in monkey urine. By contrast, the unchanged drug, the indole acetic acid metabolite formed by oxidative deamination of the dimethylaminoethyl group, and the N-oxide metabolite were the main metabolites in dog.     

Disposition and biotransformation of quinpirole, a new D-2 dopamine agonist antihypertensive agent, in mice, rats, dogs, and monkeys

The disposition and metabolism of quinpirole were studied in rats, mice, dogs, and monkeys. A single 2 mg/kg dose of 14C-quinpirole was administered orally to rats, mice, and monkeys. Dogs were given a single 0.2 mg/kg iv dose of 14C-quinpirole. Of the dose administered, 75-96% was recovered in the urine within 72 hr, with the majority being excreted during the first 24 hr. Peak plasma concentrations of radioactivity and quinpirole were coincident and were observed within 0.25 hr in rodents and at 2 hr in monkeys. Unchanged quinpirole accounted for 0.9%, 36%, and 69% respectively. Biotransformation of quinpirole was compared by quantitating the urinary metabolites by HPLC. The percentage of the radioactivity in urine representing unchanged drug was determined for each species: monkey (3%), dog (13%), mouse (40%), and rat (57%). The majority of 14C-quinpirole was shown to be biotransformed in rats, mice, and monkeys through common metabolic pathways but to various extents. Most metabolites resulted from structural alterations (N-dealkylation, lactam formation, omega and omega-1 hydroxylation) that centered around the piperidine ring portion of the molecule. These metabolites were less important in dogs. The major metabolic pathway in dogs involved hydroxylation of a methylene carbon adjacent to the pyrazole nucleus of quinpirole followed by O-glucuronidation. Evidence of metabolism of the pyrazole moiety was found in the isolation of an N-glucuronide conjugate of quinpirole from monkey urine.     

Metabolism and disposition of gemcitabine, and oncolytic deoxycytidine analog, in mice, rats, and dogs.

Gemcitabine, 2'-deoxy-2',2'-difluorocytidine, is a broad spectrum oncolytic compound with antitumor activity in solid tumor models. The pharmacokinetics, metabolism, and disposition of gemcitabine was examined in mice, rats, and dogs. All three species metabolize gemcitabine by deamination to the uracil metabolite. However, deamination in the mouse and dog was more extensive than in the rat. The mouse deaminated gemcitabine rapidly with the plasma concentration maximum of the uracil metabolite of gemcitabine being attained at 15 min postdosing compared with approximately 3 and 6 hr in the dog and rat, respectively. The rapid deamination in the mouse was also reflected in the plasma half-life of the parent compound. The mouse exhibited the shortest plasma half-life, approximately 0.28 hr, contrasted with 2.14 and 1.38 hr half-lives in rat and dog, respectively. Plasma AUC for the uracil metabolite of gemcitabine was 73%, 10.5%, and 315% of that for gemcitabine in the mouse, rat, and dog, respectively. Tissue concentrations of gemcitabine-derived radioactivity in the rat and mouse indicated that gemcitabine was rapidly distributed throughout the body. Half-lives of radioactivity in tissues of both the rat and mouse were relatively short, with the longest tissue half-lives of 5.7 and 3.0 hr, respectively. Plasma protein binding is negligible in all three species. The major route of elimination is via the urine in all three species with 76-86% of the dose excreted in the first 24 hr. The predominant radiolabeled component isolated from urine was gemcitabine in the rat and its uracil metabolite in the mouse and dog.     

Metabolites of 2-(3-trifluoromethylphenyl)tetrahydro-1,4-oxazine (CERM) 1841) in rats and dogs

1. In rats and dogs dosed with 14C-labelled 2-(3-trifluoromethylphenyl)tetrahydro-1,4-oxazine hydrochloride, the 14C was excreted in the urine. The 14C eliminated in the faeces of dog was significantly higher than for rat. 2. Conjugated metabolites, mostly glucuronides, accounted for the greater part of the urinary radioactivity in both species. 3. Biotransformation products were predominantly acids in both species, followed by significant amounts of basic metabolites, with very little neutral substances. 4. The major urinary metabolite in rats was 3-trifluoromethylbenzoic acid and 3-trifluoromethylhipuric acid. In the dog it was 3-trifluoromethylmandelic acid in addition to the benzoic acid and its conjugate. The basic products identified in the urine of both species were unchanged drug and 1-amino-2-hydroxy-2-(3-trifluoromethylphenyl)ethane, with the first predominating.     

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.     

Disposition and metabolic fate of prasugrel in mice, rats, and dogs

The disposition and metabolism of prasugrel, a thienopyridine prodrug and a potent inhibitor of platelet aggregation in vivo, were investigated in mice, rats, and dogs. Prasugrel was rapidly absorbed and extensively metabolized. In the mouse and dog, maximum plasma concentration of radioactivity was observed in less than 1 h after an oral [14C]prasugrel dose. Most of the administered prasugrel dose was recovered in the faeces of rats and dogs (72% and 52-73%, respectively), and in mice urine (54%). Prasugrel is hydrolysed by esterases to a thiolactone, which is subsequently metabolized to thiol-containing metabolites. The main circulating thiol-containing metabolite in the three animal species is the pharmacologically active metabolite, R-138727. The thiol-containing metabolites are further metabolized by S-methylation and conjugation with cysteine.     

Species comparison of pharmacokinetics and metabolism of diltiazem in humans, dogs, rabbits, and rats

Diltiazem (DTZ) is a calcium antagonist widely used in the treatment of angina and related heart diseases. It is extensively metabolized into a host of metabolites, some of which have potent pharmacological activities. In this study, the pharmacokinetics and metabolism of DTZ was investigated in humans, dogs, rabbits, and rats after each species (n = 4 or 5) was given a single oral dose of DTZ. After the drug administration, blood and urine samples were collected for 12 and 48 hrs, respectively. DTZ and six of its metabolites were quantitated in our laboratory by HPLC. The results indicated that, in humans, the major metabolites in plasma were N-monodesmethyl diltiazem (MA), deacetyl diltiazem (M1), and deacetyl N-monodesmethyl diltiazem (M2). These metabolites were also detected in the plasma of dogs, rabbits, and rats. However, there were quantitative differences. For example, in the humans and dogs, MA was the most abundant metabolite in plasma, while M1 and M2 were most prominent in the rabbits and rats, respectively, and M2 was a relatively minor metabolite in dog plasma. Less than 5% of the dose was recovered as unchanged DTZ in the urine of all the tested species. The most abundant metabolites in urine appeared to be MA and deacetyl N,O-didesmethyl diltiazem, although there were considerable inter- and intra-species variations. Two additional metabolites were detected in the urine of the humans, dogs, and rabbits, but not in the rats. They were tentatively identified as O-desmethyl diltiazem and N-O-didesmethyl diltiazem, using electron impact and ammonia chemical ionization mass spectrometry.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism of captopril-L-cysteine,a captopril metabolite,in rats and dogs

1. The metabolism of [¹⁴C]captopril-L-cysteine was studied in spontaneously hypertensive rats and pure-bred beagles after a single i.v. dose (4?mg/kg).

2. During the first 24?h, concn. of total radioactivity in blood were similar in both species.

3. Captopril was found in small amounts in the blood of both species. In rats, captopril, bound covalently but reversibly to plasma proteins (CP-PR), was the major component in blood (70%), whereas captopril-L-cysteine was a minor component (23%) of the total radioactivity. In dog blood, CP-PR constituted a smaller fraction (45%) of the total radioactivity than in the rat and captopril-L-cysteine was the major component (53%).

4. In 72?h, 89–91% of the dose was excreted in the urine of rats and dogs. Captopril-L-cysteine accounted for 7% (rat) and 68% (dog) of the radioactivity in urine; captopril accounted for 75% (rat) and 7% (dog). Other metabolites were present in the urine of both species.

5. The greater net conversion of captopril-L-cysteine to CP-PR and to captopril in rats helps explain why captopril-L-cysteine is excreted in urine as a major metabolite of captopril in dogs but only a minor one in rats.     

Metabolism of 14C-estazolam in dogs and humans

14C-Estazolam (2 mg) administered orally to dogs and human subjects was rapidly and completely absorbed with peak plasma levels occurring within one hour. In humans, plasma levels peaked at 103 +/- 18 ng/ml and declined monoexponentially with a half-life of 14 h. The mean concn. of estazolam in dog plasma at 0.5 h was 186 ng/ml. Six metabolites were found in dog plasma at 0.5 and 8 h, whereas only two metabolites were detected in human plasma up to 18 h. Metabolites common to both species were 1-oxo-estazolam (I) and 4-hydroxy-estazolam (IV). Major metabolites in dog and human plasma were free and conjugated 4-hydroxy-estazolam; the concn. were higher in dogs. After five days, 79% and 87% of the administered radioactivity was excreted in dog and human urine, respectively. Faecal excretion accounted for 19% of the dose in dog and 4% in man. Eleven metabolites were found in the 0-72 h urine of dogs and humans; less than 4% dose was excreted unchanged. Four metabolites were identified as: 1-oxo-estazolam (I), 4'-hydroxy-estazolam (II), 4-hydroxy-estazolam (IV) and the benzophenone (VII), as free metabolites and glucuronides. The major metabolite in dog urine was 4-hydroxy-estazolam (20% of the dose), while the predominant metabolite in human urine (17%) has not been identified, but is likely to be a metabolite of 4-hydroxy-estazolam. The metabolism of estazolam is similar in dog and man.     

Evaluation of the excretion, and metabolism of the cardiotonic agent bemoradan in male rats and female beagle dogs.

The excretion and metabolism of (+/-) [6-(3,4-dihydro-3-oxo-1,4[2H]-benzoxazine-yl)-2,3,4,5-tetrahydro-5-methylpyridazin-3-one] (bemoradan; RWJ-22867) have been investigated in male Long-Evans rats and female beagle dogs. Radiolabeled [14C] bemoradan was administered to rats as a singkle 1 mg/kg suspension dose while the dogs received 0.1 mg/kg suspension dose. Plasma (0-24 h; rat and dog), urine (0-72 h; rat and dog) and fecal (0-72 h; rat and dog) samples were collected and analyzed. The terminal half-life of the total radioactivity for rats from plasma was estimate to be 4.3 +/- 0.1 h while for dogs it was 7.5 +/- 1.3 h. Recoveries of total radioactivity in urine and feces for rats were 49.1 +/- 2.4% and 51.1 +/- 4.9% of th dose, respectively. Recoveries of total radioactivity in urine and feces for dogs were 56.2 +/- 12.0% and 42.7 V 9.9% of the dose, respectively. Bemoradan and a total of nine metabolites were isolated and tentatively identified in rat and dog plasma, urine, and fecal extracts. Unchanged bemoradan accounted for approimately < 2% of the dose in rat urine and 20% in rat feces. Unchanged bemoradan accounted for approximately 5% of the dose in urine and 16% in feces in dog. Six proposed pathways were used to describe the metabolites found in rats and dogs: pyridazinyl oxidations, methyl hydroxylation, hydration, N-oxidation, dehydration and phase II conjugations.     

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.