The metabolic fate of 11-bromo[15-3H]vincamine in man.

During 5 days following a single oral dose of 3H-11-bromovincamine (40 mg) to two human subjects, means of 55% and 27% of the 3H dose were excreted in the urine and faeces respectively, mainly within 24 and 48 h. Mean plasma concentrations of 3H reached a peak (1900 ng equiv./ml) at 1 h after dosing and declined biphasically with half-lives of 5 h and 11 h which were similar to half-lives for urinary excretion of 3H. Parent drug and 11-bromovincaminic acid were the major dose-related components in plasma at 1.5 and 3 h. Mean plasma concentrations of 11-bromovincamine reached a peak (620 ng/ml) at 0.75 h and declined biphasically with half-lives of about 1 h and 5 h. The major urinary metabolite was 11-bromovincaminic acid (31% dose). Also present in urine were 11-bromovincamine (3%), 11-bromoapovincamine (1%) and 2 unknown metabolites (9% and 6%). Similar metabolites were detected in faecal extracts. If inadequately stored in biological samples, 11-bromovincamine could be hydrolysed to 11-bromovincaminic acid and be epimerised to 11-bromo-epivincamine.

Metabolism of the anti-depressant lortalamine.

Humans excreted an oral dose of 5 mg of the anti-depressant lortalamine (radiolabelled with carbon-14) mainly in the urine (98% during 5 days). Plasma 14C concentrations were highest (about 44 ng equiv./ml) between 1.5-3 h when the corresponding concentrations of unchanged drug were about 17 ng/ml. Unchanged drug concentrations appeared to decline with a half-life of about 5 h. Concentrations of 14C then declined rapidly and were below the limits of detection (12 ng equiv./ml) at 24-36 h. Measurement of whole-blood 14C concentrations showed that there was some uptake into the blood cells (about 65% of the peak plasma 14C level). Radioactivity in the urine was mainly associated with unchanged drug and three metabolites. The major metabolite (about 50% urinary 14C) was identified by mass spectrometry as the N-demethylated compound and another metabolite as a keto derivative of lortalamine where oxidation had occurred in the piperidine ring.

The metabolism of the anti-inflammatory drug eterylate in rat, dog and man.

Oral doses of 14C-eterylate were well absorbed by rat and man and excreted mainly in the urine (94% dose by rat in three days and 91% by man in five days). Oral doses to dogs were excreted in similar proportions in both the urine and faeces, although faecal 14C was probably derived in part, from biliary-excreted material. Peak plasma 14C and drug concn. were generally reached between one and three hours after oral doses. In humans, only two metabolites, salicylic acid and 4-acetamido-phenoxyacetic acid, were detected in plasma. The latter was cleared more rapidly than the former and hence plasma salicyclate concn. reached a peak (10.9 and 19.8 micrograms/ml in Subjects 1 and 2, respectively) and initially declined with a half-life of about two-three hours. Plasma 4-acetamidophenoxyacetic acid concn. reached a peak (4.3, 10.0 micrograms/ml, respectively) and declined with a half-life of about one hour. Tissue concn. of 14C were generally greater in dogs than in rats. Highest conc. occurred at three hours in dogs and at one hour in rats. Apart from those in the liver and kidneys, tissue concn. were lower than those in the corresponding plasma. Unchanged drug was not detected in urine or plasma of any species and was rapidly metabolized in human plasma. The major 14C components in human urine were identified as salicyluric acid and 4-acetamidophenoxyacetic acid; minor metabolites were salicylic acid, gentisic acid and paracetamol. These metabolites were also detected in rat urine albeit in different proportions to those in human urine. Dog urine contained less of these metabolites and a major proportion of the 14C was associated with relatively non-polar components. Although salicylic acid and 4-acetamidophenoxyacetic acid were the only major circulating metabolites in man and rat, dog plasma also contained the non-polar urine metabolites.

A novel conjugate as a major metabolite of bromperidol in man.

The major urine metabolites of the neuroleptic drug, bromperidol, after oral doses to rats and dogs are p-fluorophenylacetic acid and its glycine conjugate resulting from oxidative N-dealkylation. While the same metabolites were also detected in human urine, also present was a major unknown component representing 50% of the total urine metabolites, which apparently was not formed by rats and dogs to any extent. Mass spectroscopic investigations a substituent attached to the tertiary hydroxyl group. The mass spectrum of the metabolite after trifluoroacetylation was consistent with an O-glucofuranosiduronolactone conjugate of bromperidol.

The metabolism of the hypolipidaemic drug sultosilic acid in rat, dog and man.

1. Single oral doses of the hypolipidaemic drug [35S]sultosilic acid to rats (40 mg/kg), dogs (40 mg/kg) and man (7 mg/kg) were well absorbed. During three days, means of 59.2%, 58.8% and 61.8% in urine and 37.7%, 31.9% and 19.7% in faeces, were excreted by these species respectively. Most of the dose was excreted during the first 24 h. 2. Peak plasma levels of 35S were generally reached during 1-2 h after oral doses in rats (12 micrograms equiv./ml), dogs (45 micrograms equiv./ml) and two human subjects (15.2 and 10.3 micrograms equiv./ml). In humans, peak plasma levels of unchanged drug (at 1-1.5 h) were 10.5 and 6.3 micrograms/ml. Plasma concentrations of 35S increased almost proportionately to dose in rats following oral doses of 400 and 1200 mg/kg, although in dogs, concentrations were similar at these two dose levels but several times higher than at 40 mg/kg. 3. Tissue concn. of 35S were generally higher in rats than in dogs. Highest concn. occurred at 3 h in rats and 1 h in dogs. Apart from those in the liver and kidneys, tissue concn. were appreciably lower than the corresponding plasma levels. 4. The major radioactive component in dog urine was sultosilic acid. Rat and human urine contained sultosilic acid and also two more polar major metabolites. In male and female rat urine, the proportions of these excretory products differed and the proportions in male rat urine were similar to those in human urine. Sultosilic acid was also the only component detected in dog plasma, whereas rat and human plasma also contained the two urine metabolites. Dog bile contained a conjugate of sultosilic acid. 5. The two metabolites have been identified by mass spectrometry and nuclear magnetic resonance spectroscopy as products resulting from oxidation of the methyl in the p-toluenesulphonyl group. The structures assigned are the corresponding carboxylic acid and the hydroxymethyl derivatives.

The metabolic fate of Sormodren (bornaprine hydrochloride) in animals and humans.

1. Single oral doses of the anticholinergic drug [14C]Sormodren to rats (1 mg/kg), dogs (0.3 mg/kg) and humans (0.03 mg/kg) were well absorbed. Excreted in urine and faeces were means of 31 and 70%, 53 and 39%, and 78 and 4% in rats, dogs, and humans, respectively, during five days: excretion was prolonged and still incomplete at five days in humans. 2. Peak plasma levels of 14C (scaled for dose) were generally reached within 1-2 h after oral doses in rats, 49 (ng/ml)/(mg/kg), dogs 290 (ng/ml)/(mg/kg) and humans 410 (ng/ml)/(mg/kg), and declined with half-lives of approx. 5, 12 and 30 h, in these species respectively. Repeated oral doses of [14C]Sormodren to dogs resulted in some accumulation of 14C in the plasma. 3. Tissue concn. of 14C in dogs were generally higher than those in rats, particularly in the brain, lungs and eyes. The tissue distribution of 14C in rats and dogs was consistent with that of a compound readily eliminated by both renal and hepatic routes. 4. Basic metabolites in dog and human, urine and plasma were investigated using a combination of h.p.l.c. and g.l.c.-mass spectrometry. Unchanged Sormodren was not detected in the dog samples and was only a minor component in human urine and plasma. Some metabolites were present as conjugates. 5. A basic extract of enzyme-hydrolysed dog urine (5 mg/kg dose) contained 42% of the urine 14C. The major metabolites in this fraction were identified as three isomers of monohydroxy-N-desethyl-Sormodren and three isomers of monohydroxy-Sormodren, resulting from hydroxylation in the bicyclic ring. The positions of oxidation were not determined. A similar extract from dog urine (0.3 mg/kg dose) contained 26% of the urine 14C and the major metabolites were identified as isomers of monohydroxy-N-desethyl-Sormodren. 6. A basic extract of enzyme-hydrolysed human urine (0.03 mg/kg dose) contained 23% of the urine 14C. The unchanged drug was only a minor component and most of the radioactivity was associated with five isomers of monohydroxy-Sormodren, hydroxylation having occurred in the bicyclic ring. 7. Basic extracts of dog and human plasma only contained about 10% of the plasma 14C. Metabolites were chromatographically similar to the hydroxylated metabolites identified in the corresponding urine samples.

Plasma concentration and disposition of buprenorphine after intravenous and intramuscular doses to baboons.

Buprenorphine is a newly-developed strong analgesic. A selected ion monitoring method has been developed to measure its plasma levels over the concentration range 20-3000ng ml-1. Six baboons each received intravenous and intramuscular doses of buprenorphine hydrochloride at a level of 5mg/kg in a cross-over study. The mean peak plasma concentrations (+/-standard deviation) were 2290 +/- 357ng ml-1 and 805 +/- 416ng ml-1 respectively and the corresponding times to the peak levels were 4.0 +/- 1.5 minutes and 30.3 +/- 24.6 minutes suggesting the rapid release of the drug from intramuscular sites. Comparison of areas under the plasma concentration versus time curves to 24 hours after dosing showed the mean bioavailability of buprenorphine from the intramuscular doses was 70% of that from the reference intravenous doses.

Determination of amitriptyline and its major basic metabolites in human urine by high-performance liquid chromatography.

A high-performance liquid chromatographic method for the routine, simultaneous determination of amitriptyline and its basic metabolites in human urine has been developed. 10-Hydroxylated metabolites are analyzed as their 10,11-dehydro analogs, and primary and secondary amines as their N-trifluoroacetyl derivatives. The use of gradient elution enables amitryptyline, nortriptyline trifluoroacetate, desmethylnortriptyline trifluoroacetate, and the corresponding 10, 11-dehydro analogs to be separated from both each other and from the internal standard used. In this way all six compounds may be conveniently measured in a single chromatogram, with good sensitivity and accuracy. Following administration of a single oral dose (25 mg) of amitriptyline hydrochloride to two human subjects, no unchanged drug was found in any of the urine samples analyzed up to 72 hr after dosing, and only small amounts of nortriptyline and desmethylnortriptyline were observed. 10-hydroxynortriptyline was the major biotransformation product (about 40% of the dose) in urine, with 10-hydroxyamitriptyline and 10-hydroxydesmethylnortriptyline present as minor metabolites. During 72 hr after administration, approximately 60% of the dose was recovered as these five metabolites.