Biotransformation of diclofenac sodium (Voltaren) in animals and in man. II. Quantitative determination of the unchanged drug and principal phenolic metabolites, in urine and bile.

1. Quantitative determinations of unchanged diclofenac and two of its major phenolic metabolites were made by reverse isotope dilution analysis on urine of rat, dog, rhesus monkey, baboon and man and on bile of rat, dog and man. Isotope dilution analysis was performed before and after various methods of enzymic and chemical hydrolysis. 2. The same samples were also analysed by two-dimensional t.l.c. and subsequent autoradiography, to estimate the remaining phenolic metabolites. 3. In contrast to rat, rhesus monkey, baboon and man, which excrete mainly hydroxylated metabolites, the dog does not oxidize diclofenac. Dog urine contained a relatively stable taurine conjugate of diclofenac, and in the bile an ester glucuronide was excreted, which decomposed even in weakly alkaline soln. 4. The unstable ester glucuronide found in dog bile was also demonstrable in rat bile. It presumably hydrolyses in the duodenum, releasing diclofenac which undergoes enterohepatic circulation.     

The disposition and metabolism of flurbiprofen in several species including man.

Flurbiprofen was rapidly absorbed in all species studied. 2. Half-lives of elimination measured 0 to 12 h after a single dose were: mouse 3.4 h, rat 2.5 h, dog 10.1 h, baboon 3.1 h and man 3.9 h. A second phase of elimination was seen in the dog. Flurbiprofen accumulated in the circulation of the dog on repeated dosing. 3. After dosing with [14C]flurbiprofen, tissue levels of radioactivity in dog and baboon were similar to that in plasma. In the rat, levels were slightly elevated in liver, kidney, large intestine and thyroid after repeated dosing. 4. The dog excreted equal amounts of radioactivity in urine and faeces. In other species renal excretion was the more important route. 5. Six metabolites have been detected, the most important being: 2-(2-fluoro-4'-hydroxy-4-biphenylyl)propionic acid (metabolite 1), 2-(i-fluoro-3',4'-dihydroxy-4-biphenylyl)propionic acid (metabolite 2) and 2-(2-fluoro-3'-hydroxy-4'-methoxy-4-biphenylyl)propionic acid (metabolite 3). The proportions of the metabolites and the extents of their conjugation varied among the species. 6. Metabolites were detected in the circulation of rat, mouse and baboon but not in dog and man. 7. Flurbiprofen did not affect the hepatic drug-metabolizing enzyme system of rat. 8. Flurbiprofen was extensively bound to serum protein of rat, dog, baboon and man.     

The Metabolism of Ibuprofen

Abstract

1. After oral administration ibuprofen appeared mainly in unchanged form in the plasma of rats, dogs, baboons and men. It disappeared more slowly from the plasma of dogs than from that of other species. On repeated dosing it accumulated most in dog plasma.

2. Two metabolites, 2-[4-(2-hydroxy-2-methylpropyl)phenyl]propionic acid (metabolite A) and 2-[4-(2-carboxypropyl)phenyl]propionic acid (metabolite B), were found in rat, baboon and human plasma, but not in dog plasma. Both metabolites were found in the urines of all four species, but there were marked differences in proportions and extent of conjugation.

3. Rats excreted in bile about 28% of a single intravenous dose of [¹⁴C]ibu-profen in 3 hours and a dog excreted 25% in the same period. Biliary cannulation did not influence plasma radioactivity, suggesting that little enterohepatic circulation occurred.

4. At clinically significant concentrations ibuprofen was strongly bound to plasma protein in vitro, 95% being bound in baboon, 96% in rat, and 99% in dog and human plasma.

5. After administration of either (+) or (-)-ibuprofen to man, urinary metabolites A and B were dextrorotatory.

6. In the rat ibuprofen induced neither its own metabolism nor that of sodium pentobarbitone, but sodium pentobarbitone induced the metabolism of ibuprofen.     

Major routes of naftifine biotransformation in laboratory animals and man

Following dermal or oral administration to laboratory animals and man (E)-N-methyl-N-(1-naphthylmethyl)-3-phenyl-2-propen-1-amine- hydrochloride (naftifine), the antifungal constituent of Exoderil, is quantitatively biotransformed into, and excreted as metabolites devoid of antifungal activity. The structures of 15 metabolites were elucidated. In rat urine and bile these metabolites represent 70% of the orally absorbed dose. The biotransformation routes are: N-dealkylation, oxidation or reduction of the aldehyde intermediates from a) to the corresponding carboxylic acid- or alcohol-type metabolites, arene oxide formation in the phenyl- and naphthalene moieties of Naftifine, and conjugation, mainly with glucuronic acid and glycine. Similar metabolite patterns were obtained after oral and parenteral administration. The same pathways of naftifine biotransformation were observed in all species investigated, i.e. in man, rat, dog, rabbit and guinea pig, the last two species most closely resembling to man with respect to overall kinetics and urinary metabolite pattern.     

Species differences in the metabolism of suprofen in laboratory animals and man

The metabolism of the oral anti-inflammatory agent suprofen (S), 2-4-(2-thienylcarbonyl)phenyl)propionic acid, has been studied in mice, rats, guinea pigs, dogs, monkeys, and human volunteers. The major metabolites of S in the serum, urine, and feces of these species were determined by GC/MS and HPLC techniques. The metabolic pathways of S in these species involved reduction of the ketone group to an alcohol (S-OH), hydroxylation of the thiophene ring (T-OH), elimination of the thiophene ring to a dicarboxylic acid (S-COOH), and conjugation with glucuronic acid or taurine. In 72-hr urine and feces of these species after po dosing of 1.6 to 2 mg/kg of S, S and these metabolites accounted for 46 to 92% of the dose and were mainly excreted in the urine. S was present as a major product (excreted mainly in conjugated form) in all species. S-OH was a major component in guinea pig and dog but a minor one in other species. T-OH was identified as a major metabolite in monkey, rat, mouse, and man, but a minor one in guinea pig, and it was absent in the dog. S-COOH was present as the minor metabolite in mouse and rat, and present at trace levels in dog, monkey, and man. Conjugation of the propionic acid functionality with taurine was observed only in the dog; in the other species, conjugation with glucuronic acid was extensive. Absorption parameters of S in the rat and monkey were similar to those in man; however, other species were very different from man.     

Biotransformations of glafenine in the rat and in man.

The biotransformations of a therapeutic dose of the non-narcotic analgesic, glafenine, have been studied in the rat and in man. In the rat, the ester bond is extensively hydrolysed to give glafenic acid which is the major metabolite excreted in bile and in urine. Two minor pathways have been identified one leading by hydroxylation of the benzene ring of glafenine or glafenic acid in para of the amino-substituent to the corresponding phenols, the other, by oxidation of the quinoline nitrogen of glafenic acid, to its N-oxide. In vivo this N-oxide is partly reduced into the parent compound. Hydroxyglafenic acid is the product of both direct oxidation of glafenic acid and hydrolysis of hydroxyglafenine. The glyceric esters are conjugated as glucuro-ethers and/or sulfo-esters and the carboxylic metabolites as acyl glucuronides. The conjugation rate, high for glafenine, its phenol homologue and glafenic acid, is low for hydroxyglafenic acid and the N-oxide. The analogous urinary excretion patterns in man and in the rat suggest a similarity in the biotransformation of glafenine in these two species.     

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.     

Metabolic disposition of enciprazine, a non-benzodiazepine anxiolytic drug, in rat, dog and man.

1. The excretion and metabolism of enciprazine, an anxiolytic drug, was examined in rat, dog and man. 2. In rats and dogs that received 14C-enciprazine dihydrochloride orally and by i.v. injection, the drug was well absorbed. Radioactivity was excreted predominantly in the faeces of rats, equally in urine and faeces of dogs, and to a major extent in human urine. 3. Metabolic profiles, which were evaluated in urine and in rat bile, were similar following oral and i.v. dosing to rats and dogs. 4. Unchanged drug was not detected in rat, dog or human excreta. Glucuronide conjugates of 4-hydroxyenciprazine, m-desmethylenciprazine, p-desmethylenciprazine and enciprazine were detected in the excreta of all three species. A glycol metabolite was present only in rat bile and human urine. A metabolite desmethylated in the phenyl ring of the phenylpiperazine moiety also appeared to be present only in human urine. 5. Structural confirmation of the major metabolites in human urine and rat bile was accomplished by h.p.l.c.-mass spectrometry.     

Metabolic hydroxylation of the thiophene ring: Isolation of 5-hydroxy-tienilic acid as the major urinary metabolite of tienilic acid in man and rat

The metabolism of tienilic acid, a drug containing a thiophene ring, was reinvestigated in man, rat and dog. The major urinary metabolite in man and rat was isolated and completely characterized by comparison with a synthetic compound. This metabolite derives from the hydroxylation of the thiophene ring of tienilic acid in position 5. Its isomers, 3- and 4-hydroxy-tienilic acids, were synthetized but could be detected neither in man nor in rat urine.Because of its particular behaviour toward electrophiles, 5-hydroxy-tienilic acid was found to react with diazomethane with the formation of a complex mixture of methylated products. This made difficult its measurement by a previously described GLC technique, after acidic extraction and methylation by diazomethane. A new very simple assay using HPLC and direct injection of urine is described in this paper. This assay led to a very precise and reproductible determination of tienilic acid and its hydroxylated metabolite in urine.Up to 50% of tienilic acid is excreted in man or rat urine as 5-hydroxy-tienilic acid whereas this metabolite does not appear in dog urine. These data describe the first example of metabolic hydroxylation of the thiophene ring.     

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.     

Metabolism of tracazolate. Metabolites in dog and rat urine

The urinary metabolites of tracazolate [4-n-butylamino-1-ethyl-6-methyl-1H-pyrazolo (3,4-b) pyridine-5-carboxylic acid ethyl ester], an anxiolytic agent, obtained from rats and dogs dosed with 14C-labeled tracazolate have been characterized. No unchanged tracazolate was detected. Fifteen metabolites were identified in dog urine, seven of which had not previously been found in rat blood and tissue. Eleven of these metabolites were also found in rat urine. The metabolites were formed by deesterification to the 5-carboxylic acid; N-deethylation of the pyrazole ring: oxidation at the gamma-position of the n-butylamino side chain; oxidation of the terminal carbon of this side chain; loss of the n-butylamino group; and hydroxylation of the 6-methyl group followed by condensation with the 5-carboxylic acid to form gamma-lactones. The major metabolites in dog urine were the desethyl-desbutyl-deesterified compound, the desbutyl-deesterified compound, and the desbutyl-desethyl-lactone. Loss of the butyl side chain and, also, lactone formation, appeared to occur to a lesser extent in the rat than in the dog.     

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 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.     

Disposition of cefotaxime in rat, dog and man

The excretory pathway for the elimination of 14C-cefotaxime (14C-HR 756) was found to be the same for rat, dog and man with elimination into the urine being the most important route, accounting for greater than 80% of the dosed radioactivity. The amounts of unchanged cefotaxime eliminated in the urine ranged from 20-32% in rat and dog to 56% in man. The major metabolite in each species was the microbiologically active desacetyl cefotaxime, which was present in both plasma and urine. Two further metabolites, recently identified as the stereoisomeric forms of the opened beta-lactam ring form of desacetyl cefotaxime lactone were also found in the urine of dog and man.     

Pharmacokinetics of nisoldipine. III. Biotransformation of nisoldipine in rat, dog, monkey, and man

After intraduodenal administration of 14C-labelled (+/-) 3-isobutyl-5-methyl 1,4-dihydro-2,6-dimethyl-4-(2-nitrophenyl)-pyridine-3,5-dicarboxylate (nisoldipine, Bay k 5552) to rats approx. 68% of the dose was excreted in the bile in the first 6 h. In an isolated perfused rat liver model the excretion with the bile was 56% of the total dose within 3 h. The recovery of radioactivity from orally administered [14C] nisoldipine was approx. 32% (rat), 23% (dog), 73% (monkey) and 74% (man), resp., in the urine. The unchanged drug was neither detected in the urine nor in the bile, but nisoldipine was present in plasma of the rat 30 min after dosing and up to 24 h in man. The drug was extensively metabolized: 18 biotransformation products were identified by comparison with synthetic reference compounds using combined GC-MS, 1 NMR-spectroscopy, mass spectrometry, gas chromatography/radio-gas chromatography and two-dimensional thin layer chromatography, 6 of them being quantitatively important (about 80% of the radioactivity excreted in urine). The metabolites identified accounted for approx. 82% (rat: bile and urine), 19% (dog, due to the low renal excretion), 58% (monkey: urine) and 64% (man: urine) of the excreted dose, resp. The following biotransformation steps occurred: hydroxylation of the isobutyl moiety, dehydrogenation of the 1,4-dihydropyridine system, oxidative ester cleavage, hydroxylation of one of the methyl groups in 2- or 6-position and subsequent oxidation to the carboxylic acid, oxidation of one of the methyl groups of the isobutyl moiety to the carboxyl group reduction of the aromatic nitro group (minor biotransformation reaction) and glucuronidation as phase II reaction.     

Metabolic disposition of enciprazine,a non-benzodiazepine anxiolytic drug,in rat,dog and man

1. The excretion and metabolism of enciprazine, an anxiolytic drug, was examined in rat, dog and man.

2. In rats and dogs that received ¹⁴C-enciprazine dihydrochloride orally and by i.v. injection, the drug was well absorbed. Radioactivity was excreted predominantly in the faeces of rats, equally in urine and faeces of dogs, and to a major extent in human urine.

3. Metabolic profiles, which were evaluated in urine and in rat bile, were similar following oral and i.v. dosing to rats and dogs.

4. Unchanged drug was not detected in rat, dog or human excreta. Glucuronide conjugates of 4-hydroxyenciprazine, m-desmethylenciprazine, p-desmethylenciprazine and enciprazine were detected in the excreta of all three species. A glycol metabolite was present only in rat bile and human urine. A metabolite desmethylated in the phenyl ring of the phenylpiperazine moiety also appeared to be present only in human urine.

5. Structural confirmation of the major metabolites in human urine and rat bile was accomplished by?h.p.l.c.-mass spectrometry.     

Species differences in the metabolism and excretion of fenclofenac

1. The excretion and metabolism of radiolabelled fenclofenac (2-(2, 4-dichlorophenoxy)phenylacetic acid, Flenac^R) has been studied in five species.

2. In the rat, absorption of oral doses of fenclofenac was virtually complete and elimination occurred mainly by the bile and faeces. The guinea-pig excreted equal amounts of radioactivity in urine and faeces, while in rabbit, baboon and man renal excretion was the more important route.

3. In all species the majority of excreted radioactivity was present as fenclofenac ester glucuronide. Amino acid conjunction with fenclofenac was minimal in all species studied.

4. Mono- and di-hydroxylated metabolites have been detected in urine from guineapig, baboon and man. The major hydroxylated metabolite in baboon urine has been identified as 2-(2,4-dichlorophenoxy)-5′-hydroxyphenylacetic acid.     

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.     

Disposition of cyclosporine in several animal species and man. I. Structural elucidation of its metabolites

Nine ether-extractable metabolites of cyclosporine were isolated from urine of dog and man and from rat bile and feces and purified by preparative HPLC and TLC. Structural assignments were mainly based on spectroscopic data (1H NMR, 13C NMR, MS) and the results of the amino acid analysis after hydrolysis with hydrochloric acid. All the identified metabolites retained the intact cyclic oligopeptide structure of the parent drug. Structural modifications originated from enzymatic oxidation at specific sites of the peptide subunits. Transformation processes principally involved hydroxylation at the terminal carbon atom (eta-position) of the C9-amino acid 1 and the gamma-position of the N-methylleucines 4, 6, and 9, as well as N-demethylation of the N-methylleucine 4. Regioisomeric monohydroxylated cyclosporines (metabolites 1, and 17) and N-demethylcyclosporine (metabolite 21) were the primary metabolites resulting from hydroxylation of the C9-amino-acid 1 and the N-methylleucine 9, and from N-demethylation of the N-methylleucine 4. Dihydroxylated derivatives of cyclosporine (metabolites 8, 10, and 16) were generated by further oxidation of metabolite 1 on one of the other N-methylleucines (4 or 6) or on the C9-amino acid 1, or of metabolite 17 on the N-methylleucine 9. More extensive modifications were observed for metabolite 9, a dihydroxy-N-demethylcyclosporine, which could have been formed from the dihydroxy derivative 16 by N-demethylation or from the N-demethylcyclosporine 21 by dihydroxylation. Metabolite 18 differed from 17 (monohydroxycyclosporine) by the presence of a cyclic ether moiety, formally derived by intramolecular addition of the beta-hydroxyl group to the double bond of the C9-amino acid 1.(ABSTRACT TRUNCATED AT 250 WORDS)