Metabolism, disposition, and pharmacokinetics of tracazolate in rat and dog

The metabolism, disposition, and pharmacokinetics of tracazolate, (4-butylamino-1-ethyl-6-methyl-1H-pyrazolo[3,4-b]pyridine-5-carboxylic acid ethyl ester), a novel anxiolytic agent, were studied in rat and dog following single oral and iv doses. Although tracazolate exhibits very good absorption (greater than 80%) in both species, it is extensively metabolized, accounting for low bioavailability. Excretion of 14C was rapid, with the kidney being the major organ of excretion. Tracazolate was not detected in the urine after iv doses even though measurable levels were found in blood, suggesting reabsorption of the compound by the renal tubules. The logarithm of the blood drug concentration vs. time data for both species was best described by a three-compartment open model. Mean t1/2 (beta) for tracazolate in the rat and dog were 14 and 10 hr, respectively. The distribution of radioactivity in rats showed that the concentrations of 14C and 14C-tracazolate were greater in tissues than in blood. Tracazolate was the predominant radioactive compound in brain during the first 6 hr and in fat for 96 hr. The extent and decay of tracazolate in fat strongly suggest that this tissue contributes significantly towards the equilibrium of drug between "deep body compartments" and blood. The major metabolite in blood was de-esterified tracazolate (ICI-US 7773) and in brain the gamma-ketotracazolate (ICI-US 10052).     

Tracazolate metabolites in rat tissue

Tracazolate (4-n-butylamino-1-ethyl-6-methyl-1H-pyrazolo[3,4-b] pyridine-5-carboxylic acid ethyl ester) undergoes extensive biotransformation to lipophilic metabolites following oral dosage to male rats. Twenty-one metabolites were identified in a plasma hexane extract by mass spectrometry. Coadministration of unlabeled tracazolate with its stable carbon-13 isotope expedited the isolation and identification of 11 biotransformation products. The various metabolites resulted from either hydrolysis, oxidation, dealkylation, or conversion of an ethyl group to a vinyl group and also from combinations of these biotransformation reactions. Brain extract contained tracazolate and 12 of the metabolites found in plasma. Extracts of fat contained tracazolate and nine of the plasma metabolites. An uncommon type of metabolite less polar than tracazolate (1-vinyl tracazolate) was isolated by HPLC and identified by mass spectrometry.     

Biotransformation in the monkey of cartazolate (SQ 65,396), a substituted pyrazolopyridine having anxiolytic activity

1. The metabolism of cartazolate (SQ 65,396), an anxiolytic agent, was studied in four male rhesus monkeys after oral administration. 2. Seven metabolites were identified in the pooled urine of the four monkeys. These resulted from a combination of (1) hydrolysis of the 5-carboxylic acid ethyl ester; (2) N-de-ethylation of the pyrazole ring; (3) gamma-hydroxylation of the n-butylamino side-chain; (4) removal of the n-butyl group; and (5) conjugation with beta-glucuronic acid.     

Mass spectrometric identification of urinary and plasma metabolites of 2-(6'-carboxyhexyl)-3-n-hexylcyclohexylamine, a new antiaggregating agent.

The compound IBI-P-05006, 2-(6'-carboxyhexyl)-3-n-hexylcyclohexylamine, is an antiaggregating agent under development. IBI-P-05006 is an in vitro inhibitor of platelet aggregation. The biotransformation of this compound has been studied in the dog and rat. We present here a study on the metabolites of IBI-P-05006 found in dog and rat urine, and in dog plasma. Analyses were done by gas chromatography-mass spectrometry. In dog urine 15 metabolites were identified. Some of them were also found in dog plasma and in rat urine. The unmetabolized drug was found only in plasma. 10 different hydroxylated metabolites were characterized. The hydroxyl groups were introduced in the hexyl chain in positions omega-4, omega-3, omega-2, omega-1 and omega.     

Pharmacokinetics,metabolism and excretion of the glycine antagonist GV150526A in rat and dog

1. The pharmacokinetics, metabolic fate and excretion of 3-[-2(phenylcarbamoyl) ethenyl-4,6-dichloroindole-2-carboxylic acid (GV150526), a novel glycine antagonist for stroke, in rat and dog following intravenous administration of [C14]-GV150526A were investigated. 2. Studies were also performed in bile duct-cannulated animals to confirm the route of elimination and to obtain more information on metabolite identity. 3. Metabolites in plasma, urine and bile were identified by HPLC-MS/MS and NMR spectroscopy. 4. GV150526A was predominantly excreted in the faeces via the bile, with only trace metabolites of radioactivity in urine (< 5%). Radioactivity in rat bile was predominantly due to metabolites, whereas approximately 50% of the radioactivity in dog bile was due to parent GV150526. 5. The principal metabolites in bile were identified as glucuronide conjugates of the carboxylic acid, whereas in rat urine the main metabolite was a sulphate conjugate of an aromatic oxidation metabolite. Multiple glucuronide peaks were observed and identified as isomeric glucuronides and their anomers arising from acyl migration and muta-rotation.     

Pharmacokinetics,metabolism and excretion of the glycine antagonist GV150526A in rat and dog

1. The pharmacokinetics, metabolic fate and excretion of 3-[-2(phenylcarbamoyl) ethenyl-4,6-dichloroindole-2-carboxylic acid (GV150526), a novel glycine antagonist for stroke, in rat and dog following intravenous administration of [C14]-GV150526A were investigated. 2. Studies were also performed in bile duct-cannulated animals to confirm the route of elimination and to obtain more information on metabolite identity. 3. Metabolites in plasma, urine and bile were identified by HPLC-MS/MS and NMR spectroscopy. 4. GV150526A was predominantly excreted in the faeces via the bile, with only trace metabolites of radioactivity in urine (< 5%). Radioactivity in rat bile was predominantly due to metabolites, whereas approximately 50% of the radioactivity in dog bile was due to parent GV150526. 5. The principal metabolites in bile were identified as glucuronide conjugates of the carboxylic acid, whereas in rat urine the main metabolite was a sulphate conjugate of an aromatic oxidation metabolite. Multiple glucuronide peaks were observed and identified as isomeric glucuronides and their anomers arising from acyl migration and muta-rotation.     

Biotransformation in the monkey of cartazolate (SQ 65,396), a substituted pyrazolopyridine having anxiolytic activity

1. The metabolism of cartazolate (SQ 65,396), an anxiolytic agent, was studied in four male rhesus monkeys after oral administration.

2. Seven metabolites were identified in the pooled urine of the four monkeys. These resulted from a combination of (1) hydrolysis of the 5-carboxylic acid ethyl ester; (2) N-deethylation of the pyrazole ring; (3) γ-hydroxylation of the n-butylamino side-chain; (4) removal of the n-butyl group; and (5) conjugation with β-glucuronic acid.     

Metabolism of methylphenidate in dog and rat

The urinary metabolites of methylphenidate in the dog and rat were investigated. After oral administration of 14C-labeled methylphenidate, approximately 86% and 63% of the dose was recovered in the urine of the dog and rat, respectively. Less than 1% of the dose was excreted as unchanged drug. Metabolism involved oxidation, hydrolysis, and conjugation processes. The primary hydrolytic product was alpha-phenyl-2-piperidineacetic acid (24%, dog; 35-40%, rat). The primary metabolites of oxidation were methyl 6-oxo-alpha-phenyl-2-piperidineacetate (3%, dog; 1.5%, rat) and the glucuronide of alpha-(p-hydroxyphenyl)-2-piperidineacetic acid (10%, rat). The former also underwent extensive biotransformation, including: 1) hydrolysis to the lactam acid (27%, dog; 7-10%, rat) and subsequent carboxylic acid O-glucuronidation (15%, dog); or 2) hydroxylation at the 5-position (1%, dog; 2%, rat) and subsequent hydrolysis (4%, dog; 15-17%, rat); or 3) 5-O-glucuronidation (12%, dog). Additional minor metabolites from methyl-6-oxo-alpha-phenyl-2-piperidineacetate were the phenolic O-glucuronide of methyl alpha-(p-hydroxyphenyl)-6-oxo-2-piperidineacetate (1%, dog), and the 4-O-glucuronide of methyl 4-hydroxy-6-oxo-alpha-phenyl-2-piperidineacetate (1%, dog), and the taurine amide conjugate of alpha-(p-hydroxyphenyl)-6-oxo-2-piperidineacetic acid (1%, dog). Additional products from methylphenidate conjugation included methyl 1-carbamoyl-alpha-phenyl-2-piperidineacetate (1%, dog or rat) and its carboxylic acid hydrolysis product (1%, rat). The chirality of the major metabolites isolated from dog urine showed that metabolism was partially stereoselective in all investigated cases, except in the formation of alpha-phenyl-2-piperidineacetic acid.     

Mass spectrometric identification of urinary and plasma metabolites of 6-(6'-carboxyhexyl)-7-n-hexyl-1,3-diazaspiro-[4-4]-nonan-2,4-dione, a new cytoprotective agent.

The compound IBI-P-01028, or R,S-cis-6-(6'-carboxyhexyl)-7-trans-n-hexyl-1,3-diazaspiro-[4-4]-nona n-2,4- dione, is a new cytoprotective agent under development. To study the metabolites of this compound in laboratory animals, we administered it to dogs and rats, and analyzed extracts from dog and rat urine, and from dog plasma, by GC-MS. The metabolic profiles were different in the rat and dog. In the dog (plasma and urine), one metabolite was found, and in the rat urine two other metabolites were found. The unmetabolized drug was found only in the dog plasma and urine.     

Metabolism of amineptine in rat, dog and man

After oral administration of amineptine (7-[(10-11)-dihydro-5H-dibenzo(a,d)cycloheptane-5yl] amino heptanoic acid), an original tricyclic antidepressant, seven metabolites were isolated from urine and plasma of rat, dog and man. The metabolic pathways were similar for the three species studied. The two major pathways consisted of the beta-oxidation of the heptanoic side chain leading to pentanoic (first step) and propanoic (second step) side chain metabolites and the hydroxylation of the dibenzocycloheptyl ring on carbon atom 10 (C10) causing the formation of two diastereoisomers. Lactamization by internal dehydration of beta-oxidized metabolites appeared to be a minor route of biotransformation. Conjugation reactions were of minor importance in the rat, in contrast to findings for dog and man. Urinary elimination was the major route of excretion in man while in dog and in rat faecal excretion was predominant.     

In vivo biotransformation of fenoctimine in rat,dog and man

1. The metabolism of fenoctimine (Fn) was studied in rat, dog and man following administration of ¹⁴C-Fn sulphate.

2. Seventeen Fn metabolites were isolated by hplc and tlc from rat bile, dog bile, dog urine, human urine, human faecal extracts, and human plasma and identified using nmr and MS.

3. The identified metabolites accounted for 75% of total radioactivity in rat bile, 80% in dog bile, and 40% in dog urine samples. In man, 90% of the urinary, 70% of the faecal, and > 50% of the plasma total radioactivity were identified.

4. Three major pathways for Fn metabolism were proposed. These pathways involved imino-bond cleavage, aromatic hydroxylation and oxidation of the aliphatic chain.

5. The imino-bond cleavage pathway was dominant in all species. However, the other two pathways differed in quantitative importance among the species studied.

6. The aromatic hydroxylation pathway appeared to be the most important means of biotransformation of Fn in dog since all but two of the metabolites were formed by this route.

7. The aliphatic oxidation pathway appeared to be important to the biotransformation of Fn in man and produced three major metabolites.     

Metabolism of denopamine, a new cardiotonic agent, in the rat and dog

The metabolism of denopamine, (R)-(-)-1-(p-hydroxyphenyl)-2-[(3,4-dimethoxyphenethyl)amino] ethanol, a new, orally active, selectively inotropic cardiotonic agent, was studied in the rat and dog. Animals were given single oral doses of 5 mg/kg of denopamine labeled with 14C. Denopamine was metabolized in the rat and dog by several pathways including conjugation, side chain oxidation, and ring hydroxylation followed by O-methylation. Rats excreted the drug in the urine almost entirely as unchanged drug and its phenolic O-glucuronide whereas in the dog, the major metabolites were the phenolic O-glucuronide, the alcoholic O-glucuronide, and the phenolic O-sulfate of denopamine and the phenolic O-glucuronide of 3-methoxydenopamine. Demethylation, which has been shown to be a major metabolic pathway in man, and side chain oxidation were minor pathways in the rat and dog. Furthermore, a high degree of stereoselective resistance of the alcoholic O-glucuronide of denopamine to hydrolysis by beta-glucuronidase was observed.     

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.     

Biotransformation of diclofenac sodium (Voltaren) in animals and in man. I. Isolation and identification of principal metabolites.

1. The anti-inflammatory agent diclofenac sodium (o-[(2,6-dichlorophenyl)amino]phenylacetic acid sodium salt) is extensively metabolized by rat, dog, baboon and man. The main metabolites were isolated from the urine of all species and from the bile of rat and dog and identified by spectroscopy. 2. Metabolism involves direct conjugation of the unchanged drug, or oxidation of the aromatic rings usually followed by conjugation. Sites of oxidation are either position 3' or 4' of the dichlorophenyl ring or, alternatively, position 5 of the phenyl ring attached to the acetic acid moiety. 3. In the urine of rat, baboon and man conjugates of the hydroxylated metabolites predominate, but the major metabolite in dog urine is the taurine conjugate of unchanged diclofenac. 4. In the bile of rat and dog, the main metabolite is the ester glucuroniade of unchanged diclofenac.     

Identification of metabolites of the 1",1"-dimethylheptyl analogue of cannabidiol in rat and dog in vivo

1. Metabolism of the 1",1"-dimethylheptyl analogue of cannabidiol (DMH-CBD) was studied using an isolated perfused rat liver preparation and in rat and dog urine. 2. Metabolites were identified using g.l.c.-mass spectrometry of the trimethylsilyl (TMS), methyl ester/TMS and [2H9]TMS derivatives. 3. In contrast with the metabolism of cannabidiol, the dimethylheptyl analogue gave low concentrations of metabolites in all media examined. 4. Four metabolites were found in the perfusion fluid. Two were identified as 6- and 7-hydroxy-DMH-CBD and the other two were found to be hydroxylated in the dimethylheptyl chain but at undetermined positions. 5. Five metabolites were identified in dog urine; these were the 6- and 7-mono-hydroxy and 6,7-dihydroxy derivatives of acids formed by one stage of beta-oxidation of the dimethylheptyl chain, and the 6- and 7-hydroxy derivatives of corresponding acids formed by loss of three carbon atoms from the chain. 6. Metabolic routes were very similar to those found earlier for cannabidiol.     

Metabolism of loprazolam in rat, dog and man in vivo

The metabolism of 14C-loprazolam has been studied in rat, dog and man in vivo. In rat, the major metabolic pathways were hydroxylation on the benzodiazepine ring, and reduction and acetylation of the nitro group. Both metabolites were identified by co-chromatography with standards, and were present in urine and bile conjugated with glucuronic acid. In both dog and human urine and bile significant amounts of the piperazine-N-oxide were found. This N-oxide was identified by co-chromatography with authentic compound and by mass spectroscopy. Both loprazolam and the dog biliary metabolites were hydrolysed spontaneously to polar material. Neither treatment with beta-glucuronidase nor incubation with gut microflora had any further effect. Only polar metabolites were found in dog and human faeces. The principal non-polar material found in rat plasma was the diazepine-hydroxy compound, and little loprazolam was present. Significant levels of loprazolam and lower levels of an unidentified metabolite were found in ether extracts of dog and human plasma. Both the piperazine-N-oxide and loprazolam were found in similar quantities in chloroform extracts of human plasma, and at two hours after dosage, the N-oxide and loprazolam accounted for greater than 90% of the radioactivity present in the plasma.     

Biotransformation of nimodipine in rat, dog, and monkey

14C-labelled (+/-) 3-isopropyl5-(2-methoxyethyl)1,4-dihydro-2,6-dimethyl-4- (3-nitrophenyl)-pyridine-3,5-dicarboxylate (nimodipine, Bay e 9736, Nimotop; CAS 66085-59-4) was administered orally to rat, dog, and monkey (each 5, 10, or 20 mg/kg) and intraduodenally to rat (5 mg/kg). Urine was collected over a period of 24 h (bile 6 h). Dog bile was obtained from the gall bladder 4 h after oral dosing. Rat plasma was taken 1 h p. appl. of the unlabelled compound and additionally at different times following administration of [14C]nimodipine. The metabolite profiles in the excreta were established by TLC (radioscan/autoradiography). The unchanged drug was neither detectable in urine nor in bile, but was present in rat plasma. Nimodipine was extensively metabolized. 18 metabolites were isolated by LC, HPLC, and preparative TLC and identified by comparison with the reference substances using two-dimensional TLC, HPLC, GC/radio-GC, 1H-NMR-spectroscopy, MS, and GC/MS. About 75% of the renally excreted biotransformation products, more than 50% of the metabolites present in the bile (rat, dog) and approx. 80% of the plasma metabolites (rat only) have been identified. The large number of metabolites was produced by some common biotransformation reactions: dehydrogenation of the 1,4-dihydropyridine system, oxidative ester cleavage, oxidative O-demethylation and subsequent oxidation of the resulting primary alcohol to the carboxylic acid, hydroxylation of the methyl groups at 2- or 6-position, hydroxylation of one methyl group of the isopropyl ester moiety, reduction of the aromatic nitro group, and glucuronidation as phase II-reaction.     

Study on metabolism of pyridonecarboxylic acid II. Determination of metabolites of (+-)-7-(3-amino-1-pyrrolidinyl)-6-fluoro-1-(2,4-difluorophenyl)- 1,4-dihydro-4-oxo-1,8-naphthyridine-3-carboxylic acid p-toluenesulfonate hydrate (T-3262) in blood, urine, bile, and feces

The fate of (+-)-7-(3-amino-1-pyrrolidinyl)-6-fluoro-1-(2,4-difluorophenyl-1,4- dihyro-4-oxo-1,8-naphthyridine-3-carboxylic acid p-toluenesulfonate hydrate (T-3262) was studied using T-3262 and 14C-T-3262 in various animals. 1. Metabolites in serum and urine were assayed for mouse, rat, rabbit, dog and monkey following oral administration of T-3262. In serum, besides unchanged T-3262 base, T-3262A (N-acetylated) was detected in rat, rabbit and monkey; T-3262B (deamino-hydroxylated) was detected in monkey. In urine, unchanged T-3262 base was excreted mainly. But a few of metabolites (T-3262A, T-3262B, T-3262 glucuronide, T-3262A glucuronide, T-3262B glucuronide, and unknown compound M-1) were detected, and species difference existed in types of metabolites. 2. Metabolites in bile and feces were assayed for mouse and rat following oral administration of T-3262 and 14C-T-3262. Metabolites in bile were similar to the urine, but the volume of T-3262A and T-3262A glucuronide was larger than in urine. In feces, the excreted compounds mainly consisted of unchanged T-3262 base. 3. p-Toluenesulfonic acid, which is the counter acid for T-3262 base, was absorbed following the oral administration of T-3262, and excreted in urine in the unchanged form.     

Metabolism of tamsulosin in rat and dog

1. The metabolism of tamsulosin hydrochloride (TMS), a potent α₁-adrenoceptor blocking agent, was studied after a single oral administration to rat and dog.

2. Eleven metabolites (1, 2, 3, 4 and their glucuronides, sulphates of 1 and 3, and A-1) were identified from the urine and bile of rat and dog administered TMS.

3. Unchanged drug and metabolites in urine and bile were quantified in rat and dog dosed with ¹⁴C-TMS (1?mg/kg). In rat the main metabolic routes were de-ethylation of the o-ethoxyphenoxy moiety, demethylation of the methoxybenzenesulphonamide moiety, and conjugation of the resultant metabolites by glucuronic acid and sulphuric acid. In dog the main pathways were de-ethylation of the ethoxyphenoxy moiety, conjugation of the de-ethylated product by sulphuric acid, and oxidative deamination of the side chain.

4. The organ responsible for the metabolism of TMS in rat was estimated using 9000g supernatants of liver, kidney, small and large intestine homogenate and plasma. The drug was rapidly metabolized in liver but hardly metabolized in the other organs or plasma.     

The metabolism of 5,5'-methylenedisalicylic acid in various species

Commercial methylenedisalicylic acid has been shown to be grossly impure. Pure 5,5′-methylendisalicylic acid (4,4′-dihydroxydiphenylmethane-3,3′-dicarboxylic acid) has been prepared and labelled with ¹⁴C. The fate of the pure compound in the rat, mouse, hamster, rhesus monkey, rabbit, guinea-pig and chicken has been investigated. The compound is excreted entirely unchanged in the urine and faeces in all the above species and no metabolites have been found. The biliary excretion of the injected compound is high (50–60%) in the rat and dog and low (5%) in the guinea-pig and rabbit. In the monkey, rabbit and guinea-pig, the compound is excreted almost exclusively in the urine. In the rat about 50% of the dose is excreted in the faeces. In the mouse and hamster, the main route of excretion is the urine, about 10% appearing in the faeces.