Study on metabolism of pyridonecarboxylic acid. I. Isolation and identification 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 urine

Metabolism 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) was studied. Metabolites were isolated from urine of mouse, rat, rabbit, dog and monkey following oral administration of T-3262, and identified using high performance liquid chromatography and mass spectrometry. Two metabolites, other than unchanged (+-)-7-(3-amino-1-pyrrolidinyl)-6-fluoro-1-(2,4-difluorophenyl)-1,4- dihydro-4-oxo-1,8-naphthyridine-3-carboxylic acid (T-3262 base), in which 3-aminopyrrolidinyl ring of T-3262 was metabolized, were identified as: (+-)-7-(3-acetyl-amino-1-pyrrolidinyl)-1-(2,4-difluorophenyl)-6-fluoro- 1,4- dihydro-4-oxo-1, 8-naphthyridine-3-carboxylic acid (T-3262A) in all animals: (+-)-1-(2,4-difluorophenyl)-6-fluoro-7-(3-hydroxy-1-pyrrolidinyl)-1,4- dihydro- 4-oxo-1,8-naphthyridine-3-carboxylic acid (T-3262B) in monkey. The glucuronide of T-3262 was detected in mouse, dog and monkey, the glucuronides of T-3262A and T-3262B were detected in monkey. M-I, unidentified metabolite, was detected only in mouse.     

Studies on absorption, distribution and excretion of 14C labeled (+-)-7-(3-amino-1-pyrrolidinyl)-6-fluoro-1-(2,4-difluorophenyl)-1,4- dihydro-4-oxo-1,8-naphthyridine-3-carboxylic acid p-toluene-sulfonate hydrate (14C-T-3262) in rats and mice

Absorption, distribution and excretion of T-3262 were studied in rats and mice after oral administration of 14C-T-3262. The obtained results are summarized as follows. 1. 14C-T-3262 was absorbed from the upper small intestine such as duodenum in rats. 2. Serum levels of radioactivity in rats reached the highest concentration at 1 hour after an oral administration, then gradually diminished. 3. Urinary excretion was 35% and 42% of the dosed radioactivity in rats and mice, respectively, and fecal excretion was about 65% and 56% of the dosed radioactivity in rats and mice, respectively. 4. Biliary excretion in rats was about 27% of the dosed radioactivity after an oral administration of 14C-T-3262, and a half amount of excreted radioactivity was reabsorbed from the intestine. 5. Radioactivity was distributed the most into the kidney and the liver among all organs other the stomach and the intestine. Radioactivity was widely distributed into other organs such as spleen, adrenal, pancreas, lung, heart and thymus. But the distribution of radioactivity into the brain was little. 6. The distribution of 14C-T-3262 was also studied with whole body autoradiography in normal male mice and pregnant mice. The radioactivity was distributed widely to whole tissues except brain, spinal cord and eye ball. In pregnant mice, radioactivity levels in the fetuses were the same as the blood level of the mother mice. 7. The binding rate of 14C-T-3262 to rats and mice serum proteins was 63-66%. 8. Urinary and fecal excretion patterns of radioactivity in mice after multiple oral administration of 14C-T-3262 for 10 days were similar to those after a single administration. This result suggests that T-3262 did not accumulate in body. 9. After oral administration of 14C-T-3262 to nursing rats, the secreted radioactivity level in the milk was higher than the blood level.     

Metabolism of [2-14C]p-hydroxyphenyl acetic acid in rat, monkey and human hepatocytes and in bile-duct cannulated rats

We determined the metabolism of [2-(14)C]p-hydroxyphenyl acetic acid (p-HPA) in rat (male, Sprague-Dawley), monkey (male, Cynomolgus), and human (male, Caucasian) hepatocytes, and in bile-duct cannulated (BDC) rats (male, Sprague-Dawley). Unchanged p-HPA ranged from 87.0 to 92.6% of the total radioactivity (TRA) in the extracts of rat, monkey, and human hepatocytes. Metabolites M1 (a glucuronide conjugate of p-HPA) and M2 (a glycine conjugate of p-HPA) were detected, accounting for 1-4% of TRA. After an oral dose of [2-(14)C]p-HPA to BDC rats, p-HPA-related components was predominantly excreted in urine, accounting for 83% of the dose. Bile excretion was limited, accounting for only 1.5% of the dose. Unchanged p-HPA was the predominant radioactivity in plasma (84.6% of the TRA in 1-h pooled plasma) and urine (69.6% of the dose). Metabolites M1, M2, and M3 (a glucuronide of p-HPA) were all detected in plasma, urine, and bile as minor components. In summary, p-HPA was not metabolized extensively in rat, monkey, and human hepatocytes. In rats, absorption and elimination of p-HPA were nearly complete with urinary excretion of the unchanged p-HPA as the predominant route of elimination after oral dosing. No oxidative metabolites were detected, suggesting a minimal role for P450 enzymes in its overall metabolic clearance. Therefore, p-HPA has a low potential for drug-drug interactions mediated by the concomitant inhibitors and inducers of P450 enzymes.     

Metabolism and disposition of the dopamine agonist 2-(N-propyl-N-2-thienylethylamino)-5-hydroxytetralin in conscious monkeys after subsequent i.v. oral, and ocular administration

The metabolism of 2-(N-propyl-N-2-thienylethylamino)-5-hydroxytetralin (N-0437) was investigated in conscious monkeys after subsequent i.v., oral, and ocular administration. The administration of the drug caused some physiological effects, such as bradycardia and sedation of the monkeys. During a collection period of 120 hr, on average 83% was recovered after iv administration and 90% after p.o. dosing. After i.v. administration, 44% was excreted in the bile, as compared to 38% in the urine and about 1% in the feces. After oral administration, bile is the major excretion route, accounting for about 60% of the dose, as compared to 25% in the urine and about 5% in the feces. After ocular administration, on average 62% was recovered after 7 hr, excreted in bile and urine in about equal amounts. All percentages given above reflect the total amount of radioactivity recovered, thus comprising the unchanged drug plus various metabolites. After all three dosing routes, N-0437 was metabolized almost completely prior to elimination. Direct glucuronidation of the phenolic group proved to be the major metabolic pathway of N-0437, comprising about 44% of the dose after i.v. and ocular administration and 72% after oral dosing. Hydroxylation of N-0437 at the position ortho to the phenolic group present yielded a catechol intermediate, which was excreted as a glucuronide and accounted for about 10% of the dose. In the monkey, a clear regioselective preference towards glucuronidation at the 6-position was observed. Besides the glucuronide, the sulfoconjugate of N-0437 was a major metabolite after i.v. and ocular administration, accounting for about 15% of the dose.(ABSTRACT TRUNCATED AT 250 WORDS)     

A study on the distribution of T-3262 (tosufloxacin tosilate) in salivary glands of rats using microautoradiography

The distribution of T-3262 (tosufloxacin tosilate) in salivary glands of rats was investigated with frozen-microautoradiography. One and 4 hours after oral administration of 14C-T-3262 at 100 mg/kg to rats submandibular glands, parotid glands and sublingual glands were removed, and a microautoradiogram of each was made. In the submandibular gland and the parotid gland 14C-T-3262 was distributed at high levels throughout the glands taken at 1 and 4 hours after administration, but lower levels than the other glands were found in the sublingual gland at 1 hour. The results of this study suggested that T-3262 penetrates effectively into the saliva, because 14C-T-3262 is distributed well into glandular acinus, striated duct and excretory duct. The microautoradiography was a useful and reliable method for investigating the distribution of antimicrobial agents in salivary glands.     

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.     

Pharmacokinetics of ciprofloxacin. 1st communication: absorption, concentrations in plasma, metabolism and excretion after a single administration of [14C]ciprofloxacin in albino rats and rhesus monkeys

The absorption, disposition, metabolism and excretion of 1-cyclopropyl-6-fluoro-1,4-dihydro-4-oxo-7-(1-[U-14C]piperazinyl)-3- quinoline carboxylic acid (ciprofloxacin, Bay o 9867; designated tradename: Ciprobay) were studied following a single intraduodenal (rat), oral and intravenous (rat, monkey) administration, respectively, in the dose range 5 to 30 mg/kg body weight. Ciprofloxacin was absorbed partially (30 to 40%) in both species. Peak plasma concentrations of radioactivity were measured approximately 1 h (rat) or 2 h (monkey) after oral dosing. Terminal half-lives ranging from 26 to 44 h were determined for the elimination of radioactivity from the plasma (observation time up to 48 h after dosing). Nearly identical concentrations of the unchanged drug and total radioactivity were found during the first 7 or 8 h for the monkey after intravenous injection and for the rat also after oral administration, respectively. After reaching maximum concentration of 0.25 microgram/ml after administration of 5 mg/kg to rats and 0.88 microgram/ml after dosing with 30 mg/kg to a rhesus monkey, the unchanged drug was eliminated from plasma corresponding to half-lives ranging from 3 h (rat) and 4.4 h (monkey). The radioactivity was rapidly and completely excreted in both species. After intravenous administration about 51% (rat) and 61% (monkey), respectively, was excreted via the kidney. After oral dosing renal excretion amounted to 6-14% (rat) and 30% (monkey), respectively. Maximum residues in the body (exclusive gastrointestinal tract) of 1% of dose occurred in both species. In urine and feces of rats predominantly the unchanged drug and a conjugate were detected.(ABSTRACT TRUNCATED AT 250 WORDS)     

Application of 1 H- and 19 F-NMR spectroscopy in the investigation of the urinary and biliary excretion of 3,5-, 2,4-ditrifluoromethylbenzoic and pentafluorobenzoic acids in rat

1. The metabolism and excretion of 2,4-, 3,5-ditrifluoromethyl- and pentafluorobenzoic acids were studied in the bile-cannulated rat using 1 H- and 19 F-NMR spectroscopy following intraperitoneal administration at 50?mg kg -1. 2. Pentafluorobenzoic acid was excreted in the urine entirely unchanged. No detectable compound or metabolites were eliminated in the bile. A total of 63.5 ± 6.7% of the dose was recovered in the 24-h collection period. 3. In the case of 2,4-ditrifluromethyl benzoic acid, 83.9 ± 5.2% of the dose was recovered in the 24h after administration, with about 52% being excreted in the urine and 32% in the bile. The majority of the material present in the urine was unchanged parent compound. In bile, some 60% of the compound-related material excreted was present as transacylated ester glucuronide conjugates. 4. For 3,5-ditrifluoromethylbenzoic acid, 49.6 ± 5.3% of the dose was recovered in the 24-h collection period, with about 22% being excreted in the urine and 28% in the bile. The material excreted in both the urine and bile was a mixture of the parent acid and transacylated ester glucuronides. 5. Urinary excretion in bile-cannulated animals was similar to that found in studies using non-cannulated animals dosed at 100mg kg -1.     

Toxicokinetics of 1,2-diethylbenzene in male Sprague-Dawley rats-part 1: excretion and metabolism of [(14)C]1,2-diethylbenzene.

The excretion and metabolism of neurotoxic 1,2-diethylbenzene (1, 2-DEB) was studied in male Sprague-Dawley rats after i.v. (1 mg/kg) or oral (1 or 100 mg/kg) administration of 1,2-diethyl[U-(14)C]benzene ([(14)C]1,2-DEB). Whatever the treatment, radioactivity was mainly excreted in urine (65-76% of the dose) and to a lower extent in feces (15-23% of the dose), or via exhaled air (3-5% of the dose). However, experiments with rats fitted with a biliary cannula demonstrated that about 52 to 64% of the administered doses (1 or 100 mg/kg) were initially excreted in bile. Biliary metabolites were extensively reabsorbed from the gut and ultimately excreted in urine after several enterohepatic circulations. Insignificant amounts of unchanged 1,2-DEB were recovered in the different excreta (urine, bile, and feces). As reported previously, presence of 1-(2'-ethylphenyl)ethanol (EPE) was confirmed in urine and demonstrated in bile and feces. The two main [(14)C]1,2-DEB metabolites accounted for 57 to 79% of urinary and biliary radioactivity, respectively. Beta-Glucuronidase hydrolysis and electron impact mass spectra results strongly supported their glucuronide structure. Additionally, these two main metabolites were thought to be the glucuronide conjugates of the two potential enantiomers of EPE. The results indicate that the main initial conversion step of the primary metabolic pathway of 1,2-DEB appears to be the hydroxylation of the alpha-carbon atom of the side chain. The presence of two glucuronide conjugates of EPE in the urine in a ratio different from one suggests that the metabolic conversion of 1, 2-DEB is under stereochemical control.     

Studies of metabolic fate of a new antiallergic agent, azelastine (4-(p-chlorobenzyl)-2-[N-methylperhydroazepinyl-(4)]-1-(2H)-phthalazinone hydrochloride)

The metabolic fate of a new antiallergic agent, azelastine (4-(p-chlorobenzyl)-2-[N-methylperhydroazepinyl-(4)]-1-(2H)-phthalazinone hydrochloride) in rats and guinea pigs was investigated using its 14C-labelled compound. The blood level of radioactivity reached the maximum at 1-1.5 hr after oral administration, indicating the rapid absorption of the drug from gastrointestinal tract. A high concentration of radioactivity was detected in the lung of both species following either oral or intravenous administration. The major pathway of excretion of radioactivity was by way into feces, in both species. The radioactivity excreted in feces was attributable to that which was excreted in bile and exsorbed into gastrointegtinal tract. When the drug was given to pregnant rats, the concentration of radioactivity in the fetus was significantly lower than those in placenta and uterus, indicating the limited placental transfer of the drug. The successive oral administration of the drug in lower doses exerted no effect on the activity of microsomal drug-metabolizing enzymes of rat liver, while in higher doses, had a slight effect.     

Pharmacokinetic, distribution, metabolism, and excretion of (Z)-2-amino-1,5-dihydro-1-methyl-5-[4-(mesyl)benzylidene]-4H-imidazol-4-one mesilate (ZLJ-601) in Sprague-Dawley rats

(Z)-2-amino-1,5-dihydro-1-methyl-5-[4-(mesyl)benzylidene]-4H-imidazol-4-one mesilate (ZLJ-601) is an imidazolone COX/5-LOX inhibitor, which has excellent anti-in?ammatory activity with an improved gastrointestinal safety profile. The purpose of this study was to evaluate the in vivo absorption, distribution, metabolism, and excretion of ZLJ-601 in Sprague-Dawley rats. After intravenous or intragastric administration to rats, the concentration of ZLJ-601 in plasma, bile, urine, feces and various types of tissues was detected by LC-MS. We also conducted the identification of metabolites using tandem mass spectrometry. After the intravenous administration, the t(1/2) ranged from 38.71 to 42.62 min and the AUC increased in a dose-proportional manner. After oral dosing, the plasma level of ZLJ-601 peaked at 28.33 min, having a C(max) value of 0.26 mg/l, and the bioavailability was only 4.92%. The highest tissue concentration of ZLJ-601 was observed in lung and kidney, but it was not found in brain. The majority of unchanged ZLJ-601 was excreted in urine (～35.87%) within 36 h. Two main metabolites are the hydroxylation product and the glucuronide conjugate of the hydroxylation product.     

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.     

The Metabolic Fate of the Coronary Dilator 4-(3,4,5-Trimethoxycinnamoyl)-1-(N-Isopropylcarbamoylmethyl)- Piperazine in the Rat,Dog and Man

1. An oral dose of the coronary dilator 4-(3,4,5-trimethoxycinnamoyl)-1- (N-isopropylcarbamoylmethyl)-piperazine was readily absorbed and more than 75% of the dose was excreted within 24 h by the rat, dog and man. In 4 days, rat, dog and man excreted in the urine and faeces respectively 32.5 and 62.3%, 43.9 and 49.1%, and 57.8 and 43.3%. Faecal radioactivity was mainly excreted via the bile.

2. Plasma concentrations of radioactivity reached a maximum within 1 h in rats and dogs and within 2 h in man. For several h, more than 50% of the radioactivity circulating in the plasma of rats and more than 80% in man was due to unchanged drug.

3. Sequential whole-body autoradiography of the rat indicated that much of the radioactivity was distributed in the liver, kidneys and gastrointestinal tract and that there was significant uptake into the heart and lungs.

4. Although similar metabolites were excreted by the rat, dog and man, the relative proportions differed. 11.7, 2.3 and 28.8% respectively of the unchanged drug were excreted in the urine and 13.1, 19.5 and 10.4% respectively of the principal metabolite a glucuronide whose exact structure was not determined. Other metabolites included 4-(3,4,5-trimethoxycinnamoyl)-1-carbamoylmethyl piperazine and N-(3,4,5-trimethoxycinnamoyl)-piperazine.     

The metabolism of (+-)-methylephedrine in rat and man

1. Urinary metabolites of methylephedrine and their excretion after oral administration to rat and human volunteers have been studied. 2. The unchanged drug, ephedrine, norephedrine, their aromatic hydroxylated compounds and methylephedrine N-oxide were found in rat urine. The same metabolites, except the p-hydroxylated metabolites, were detected in human urine. The most abundant metabolite in rat urine was methylephedrine N-oxide, and in human urine was the unchanged drug. 3. Metabolites excreted in three days after administration of the drug to rat amounted to about 54% of the dose and those after administration to man, 70-72%.     

Absorption, distribution and excretion of 2,4-diamino-6-(2,5-dichlorophenyl)-s-triazine maleate in rats, dogs and monkeys

Absorption, distribution and excretion of 2,4-diamino-6-(2,5-dichlorophenyl)-s-triazine maleate (MN-1695) were studied in rats, dogs and monkeys after administration of [14C]-MN-1695. MN-1695 was found to be well absorbed from the small intestine after oral administration in all species examined. Plasma level of unchanged MN-1695 reached a maximum at 1 to 4 h after oral administration of [14C]-MN-1695 in rats, dogs and monkeys. The mean elimination half-life of unchanged MN-1695 from plasma was about 3, 4 and 50 h in rats, dogs and monkeys, respectively. Tissue levels of radioactivity after oral administration of [14C]-MN-1695 in rats indicated that [14C]-MN-1695 was distributed throughout the body and the radioactivity in tissues disappeared with a rate similar to that in plasma. A stomach autoradiogram after intravenous administration of [14C]-MN-1695 in the rat revealed the radioactivity localized in the gastric mucosa where MN-1695 was assumed to exert its pharmacological activity. In pregnant rats, [14C]-MN-1695 was distributed to the fetus with levels similar to maternal blood levels. After oral administration of [14C]-MN-1695 in rats, 39 to 46% of the dose was excreted into the urine and 50 to 63% of the dose into the feces, within 96 h. In dogs, about 40% of the dose was excreted into the urine and about 50% of the dose into the feces, within 6 days after oral administration. In monkeys, within 14 days after oral administration, about 60 and 30% of the dose were excreted into the urine and feces, respectively, and the main excretion route was the urine.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Identification of ginkgolic acid (15:1) metabolites in rats following oral administration by high-performance liquid chromatography coupled to tandem mass spectrometry

1.?In this article, metabolites of ginkgolic acid (GA) (15:1) in rats plasma, bile, urine and faeces after oral administration have been investigated for the first time by high-performance liquid chromatography coupled to tandem mass spectrometry (HPLC-MS/MS) with the aid of on-line hydrogen/deuterium (H/D) exchange technique and β-glucuronidase hydrolysis experiments.

2.?After oral administration of GA (15:1, M0) to rats at a dose of 10?mg/kg, it was found that metabolites M1-M5 together with parent compound (M0) existed in rat plasma; parent compound (M0) and metabolites M2–M5 were observed in rat bile, and parent compound (M0) with metabolites M1 and M2 were discovered in rat faeces, and there was no parent compound and metabolite detectable in rat urine.

3.?Two oxidative metabolites of GA (15:1, M0) were identified as 2-hydroxy-6-(pentadec-8-enyl-10-hydroxy) benzoic acid (M1) and 2-hydroxy-6-(pentadec-8-enyl-11-hydroxy-13-carbonyl) benzoic acid (M2), respectively. Metabolites M3, M4 and M5 were identified as the mono-glucuronic acid conjugates of parent compound (M0), M1 and M2, respectively.

4.?The results indicated that M1 and M2 with parent compound (M0) were mainly eliminated in faeces and three glucuronide metabolites (M3, M4 and M5) excreted in bile as the predominant forms after oral administration of GA (15:1) to rats.     

The metabolism of (-)-3-phenoxy-N-methylmorphinan in dogs

The disposition of radioactive (-)-3-phenoxy-N-methyl[2-3H]morphinan in dogs after oral administration has been investigated. Unchanged drug was not found in bile, urine, or feces. Excretion of total radioactivity in feces ranged from 67 to 78% of an oral dose. Two unconjugated metabolites were isolated from feces and identified by NMR and GC/MS. Both were substituted on the phenoxy group; they were found to be the p-hydroxy (pOH-PMM) and the m-methoxy-p-hydroxy (mOCH3-pOH-PMM) metabolites. Further, levorphanol and norlevorphanol were identified in feces both as free and conjugated metabolites, as well as a small amount of levomethorphan. Urine contained mostly unknown metabolites and conjugated levorphanol and pOH-PMM. Although the glucuronide of mOCH3-pOH-PMM was the major metabolite in bile, smaller amounts of the glucuronide and sulfate conjugated of both levorphanol and pOH-PMM were also found. Estimates for the total urinary and fecal excretion (as percentages of the dose) by two dogs for the five known metabolites were as follows: levorphanol, 18.8-21.5%; pOH-PMM, 14.4-20.6%; mOCH3-pOH-PMM, 14.9%; norlevorphanol, 2.8-6.1%; levomethorphan, 0.5%. Two of these metabolites, pOH-PMM and levorphanol, are potent analgesics.     

Application of (1)H- and (19)F-NMR spectroscopy in the investigation of the urinary and biliary excretion of 3,5-, 2,4-ditrifluoromethylbenzoic and pentafluorobenzoic acids in rat

1. The metabolism and excretion of 2,4-, 3,5-ditrifluoromethyl- and pentafluorobenzoic acids were studied in the bile-cannulated rat using (1)H- and (19)F-NMR spectroscopy following intraperitoneal administration at 50 mg kg(-1). 2. Pentafluorobenzoic acid was excreted in the urine entirely unchanged. No detectable compound or metabolites were eliminated in the bile. A total of 63.5 +/- 6.7% of the dose was recovered in the 24-h collection period. 3. In the case of 2,4-ditrifluromethyl benzoic acid, 83.9 +/- 5.2% of the dose was recovered in the 24h after administration, with about 52% being excreted in the urine and 32% in the bile. The majority of the material present in the urine was unchanged parent compound. In bile, some 60% of the compound-related material excreted was present as transacylated ester glucuronide conjugates. 4. For 3,5-ditrifluoromethylbenzoic acid, 49.6 +/- 5.3% of the dose was recovered in the 24-h collection period, with about 22% being excreted in the urine and 28% in the bile. The material excreted in both the urine and bile was a mixture of the parent acid and transacylated ester glucuronides. 5. Urinary excretion in bile-cannulated animals was similar to that found in studies using non-cannulated animals dosed at 100mg kg(-1).