Disposition of the novel serotonin agonist, LY228729, in monkeys and rats.

The disposition of a novel 5HT-1a agonist, LY228729, was studied in rats after oral administration and in monkeys after both i.v. and oral administration of a radiolabeled drug. Plasma concentrations of LY228729 declined with a half-life of 2.3 and 1.5 hr in monkeys after oral dosing and i.v. administration, respectively, and 1.9 hr in rats dosed orally. Peak plasma concentrations of the N-despropyl metabolite were greater than the parent drug following oral administration in both rats and monkeys and declined with a half-life of 3.2-3.5 hr. Plasma levels of total radioactivity rapidly exceeded that of the parent drug in both species. Radioactivity was eliminated more slowly, with terminal half-lives of 39.4 hr in the monkey and 48.6 hr in the rat. The parent drug and its despropyl metabolite accounted for only a small percentage of the total radioactivity in the plasma. Following i.v. and oral administration, radioactivity was eliminated predominantly in the urine of monkeys, but was distributed evenly between the urine and feces of rats. Parent drug and the N-despropyl metabolite were the major products in rat urine. In the monkey, the major metabolite was an uncharacterized polar compound.     

Pharmacokinetics and metabolism of dofetilide in mouse, rat, dog and man.

1. Pharmacokinetics of dofetilide were studied in man, dog, rat and mouse after single i.v. and oral doses of dofetilide or 14C-dofetilide. 2. Dofetilide was absorbed completely in all species. Low metabolic clearance in man resulted in complete bioavailability following oral administration. Higher metabolic clearance in rodents, and to a lesser extent dogs, resulted in decreased bioavailability because of first-pass metabolism. 3. Following i.v. administration, the volume of distribution showed only moderate variation in all species (2.8-6.3 l/kg). High plasma clearance in rodents resulted in short half-life values (mouse 0.32, male rat 0.5 and female rat 1.2 h), whilst lower clearance in dog and man gave longer terminal elimination half-lives (4.6 and 7.6 h respectively). 4. After single i.v. doses of 14C-dofetilide, unchanged drug was the major component excreted in urine of all species with several metabolites also present. 5. Metabolites identified in urine from all species were formed by N-oxidation or N-dealkylation of the tertiary nitrogen atom of dofetilide. 6. After oral and i.v. administration of 14C-dofetilide to man, parent compound was the only detectable component present in plasma and represented 75% of plasma radioactivity. No single metabolite accounted for greater than 5% of plasma radioactivity.     

Metabolic fate of premazepam, a new anti-anxiety drug, in the rat and the dog

A study of the disposition and metabolism of premazepam, 3,7-dihydro-5-phenyl-6,7-dimethyl-pyrrole[3,4-e][1,4]diazepin-2-(1 H) -one, a new anti-anxiety agent, was carried out in rats and dogs given the 14C-labeled compound iv and po. In both species, after oral administration, both total radioactivity and the unchanged drug are rapidly absorbed and peak plasma levels are reached within 0.5-1 hr in rats and 2 hr in dogs. Unchanged premazepam is cleared faster in rats than in dogs, with half-lives about 1.7 and 2.7 hr, respectively. Following oral dosage, two-thirds of the dose is eliminated in urine. From the urine of the two species, eight metabolites and unchanged premazepam were identified. N-7-Desmethyl premazepam (l) is the major metabolite in rat urine (18% of the dose) but is not present in dog urine, while 6-hydroxymethyl premazepam is the most abundant metabolite in dog urine (25% of the dose) but is absent in rat urine. Metabolites III and IV from rat and dog urine are stable derivatives of the intermediate formed by the cleavage of the imine bond of the diazepine ring. A successive hydrolysis of the amidic bond of the same intermediate originates metabolites V-VIII, which are quantitatively minor ones.     

Comparative biodisposition and metabolism of 14C-(+/-)-fenfluramine in mouse, rat, dog and man.

1. The comparative metabolism of fenfluramine was investigated in mouse, rat, dog and man following a single oral dose of 14C-(+/-)-fenfluramine hydrochloride (1 mg/kg), and also in rat after eight consecutive 12-h subcutaneous doses (24 mg/kg). 2. Main route of excretion of radioactivity in all species and at all doses was into urine (> 80%), with only minor amounts of radioactivity found in faeces. 3. From all species examined a total of 11 metabolites were observed in urine and plasma by t.l.c. and h.p.l.c. analysis and no metabolite was present in the plasma which was not present in urine. 4. All species dealkylate fenfluramine to the active metabolite norfenfluramine, to a relative greater or lesser extent, with plasma metabolic ratios (norfenfluramine/fenfluramine) showing inter-animal variation (rat > dog > mouse = man). 5. These differences are due to the efficient deamination of both compounds to polar inactive metabolites in man, with less dealkylation and lower plasma levels of norfenfluramine compared with the other species studied. 6. In conclusion, major species differences in the metabolism of (+/-)-fenfluramine, both qualitative and quantitative were observed, and no one species had a similar metabolic profile to that found in man.     

Pharmacokinetics of iododoxorubicin in the rat, dog, and monkey.

The pharmacokinetics of iododoxorubicin (I-DOX) have been studied after single dose administration in the rat (iv and po), dog (iv and po), and monkey (iv). Plasma levels and amounts in urine were monitored by HPLC for both I-DOX and its biologically active metabolite, iododoxorubicinol (I-DOXOL). Plasma levels of I-DOX after iv administration could be described by a three-exponential curve with extremely fast initial phase. Terminal elimination half-lives of I-DOX were similar, 6-7 hr, in all three species. Body weight-normalized clearance (CL) and distribution volumes (Vd) of I-DOX were lower in the dog, but were similar in rat and monkey. The pharmacokinetic parameters also implied metabolic differences between species. Mean I-DOXOL/I-DOX AUC ratios were 0.02, 0.47, and 0.58, respectively, in rat, dog, and monkey, values considerably lower than reported in human studies. I-DOXOL remained slightly longer in the body than I-DOX, as seen both from terminal half-lives (9-11 hr) and mean residence times. In all species, renal excretion was virtually negligible: the amount of I-DOX + I-DOXOL in urine was less than 2% of dose. Mean bioavailabilities of I-DOX were 0.23 and 0.46 in rat and dog, respectively, and, in the latter, about half of I-DOXOL formation occurred during or before the first pass.     

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.     

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)     

Disposition and metabolic fate of 14C-quazepam in man

The absorption, metabolism, and excretion of quazepam, a new benzodiazepine hypnotic, was investigated in six normal male volunteers after oral administration of 25 mg 14C-quazepam in solution. Quazepam was well absorbed. Plasma radioactivity peaked (324.6 ng quazepam eq/ml) 1.75 hr postdose. Unchanged quazepam reached its maximum plasma level (148 ng/ml) at 1.5 hr with an apparent absorption half-life of 0.4 hr. Major plasma metabolites of quazepam were 2-oxoquazepam (OQ), obtained by replacement of S by O,N-desalkyl-2-oxoquazepam (DOQ), and 3-hydroxy-2-oxoquazepam (HOQ) glucuronide. Both OQ and DOQ are pharmacologically active. Plasma elimination half-lives for quazepam, OQ, DOQ, and radioactivity were 39, 40, 69, and 76 hr, respectively. The respective AUC (120 hr) values were 715, 438, 3323, and 11402 hr X ng/ml. Approximately 54% of the radioactive dose was excreted in the urine (31.3%) and feces (22.7%) over a 5-day period. HOQ glucuronide was the major urinary metabolite of quazepam. Other metabolites present in the urine in relatively large amounts were glucuronides of DOQ and HDOQ.     

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, distribution, and metabolism of [14C]sunitinib in rats, monkeys, and humans

Sunitinib is an oral multitargeted tyrosine kinase inhibitor approved for the treatment of advanced renal cell carcinoma, imatinib-refractory gastrointestinal stromal tumor, and advanced pancreatic neuroendocrine tumors. The current studies were conducted to characterize the pharmacokinetics, distribution, and metabolism of sunitinib after intravenous and/or oral administrations of [(14)C]sunitinib in rats (5 mg/kg i.v., 15 mg/kg p.o.), monkeys (6 mg/kg p.o.), and humans (50 mg p.o.). After oral administration, plasma concentration of sunitinib and total radioactivity peaked from 3 to 8 h. Plasma terminal elimination half-lives of sunitinib were 8 h in rats, 17 h in monkeys, and 51 h in humans. The majority of radioactivity was excreted to the feces with a smaller fraction of radioactivity excreted to urine in all three species. The bioavailability in female rats was close to 100%, suggesting complete absorption of sunitinib. Whole-body autoradioluminography suggested radioactivity was distributed throughout rat tissues, with the majority of radioactivity cleared within 72 h. Radioactivity was eliminated more slowly from pigmented tissues. Sunitinib was extensively metabolized in all species. Many metabolites were detected both in urine and fecal extracts. The main metabolic pathways were N-de-ethylation and hydroxylation of indolylidene/dimethylpyrrole. N-Oxidation/hydroxylation/desaturation/deamination of N,N'-diethylamine and oxidative defluorination were the minor metabolic pathways. Des-ethyl metabolite M1 was the major circulating metabolite in all three species.     

Absorption, distribution and excretion of lacidipine, a dihydropyridine calcium antagonist, in rat and dog

1. The absorption, distribution and excretion of lacidipine have been studied in rat and dog after i.v. (0.05 mg/kg for rat; 0.5 mg/kg for dog) and oral dosage (2.5 mg/kg for rat; 2.0 mg/kg for dog). 2. Lacidipine was rapidly and extensively absorbed after oral dosing, in both species. Oral bioavailability was up to 26% in rat and up to 32% in dog, due to extensive first-pass metabolism. 3. After oral administration, peak levels of radioactivity were reached at 4-8 h in rat and 1-2 h in dog. Unchanged lacidipine peaked at 1-2 h in both species. Plasma levels of radioactivity were higher in female rats than in males but there was no difference in levels of unchanged drug. 4. After i.v. dosing the terminal half-life of unchanged drug was 2.9 h in rat and 8.2 h in dog. The half-life of radioactivity in plasma was longer in both species. 5. After both routes of administration, radioactivity was rapidly distributed in rat tissues with the highest concentration in liver, fat and gastrointestinal tract. Only traces of radioactivity were detected in the CNS and in rat foetuses. 6. Extensive biliary elimination occurred, and most of the radioactivity (73-95%) was excreted in the faeces after i.v. or oral administration. 7. The compound was extensively metabolized, no significant amount of unchanged drug was excreted in bile or urine.     

Absorption,distribution and excretion of lacidipine,a dihydropyridine calcium antagonist,in rat and dog

1. The absorption, distribution and excretion of lacidipine have been studied in rat and dog after i.v. (0.05 mg/kg for rat; 0.5 mg/kg for dog) and oral dosage (2.5 mg/kg for rat; 2.0 mg/kg for dog).

2. Lacidipine was rapidly and extensively absorbed after oral dosing, in both species. Oral bioavailability was up to 26% in rat and up to 32% in dog, due to extensive first-pass metabolism.

3. After oral administration, peak levels of radioactivity were reached at 4-8 h in rat and 1-2 h in dog. Unchanged lacidipine peaked at 1-2 h in both species. Plasma levels of radioactivity were higher in female rats than in males but there was no difference in levels of unchanged drug.

4. After i.v. dosing the terminal half-life of unchanged drug was 2.9 h in rat and 8.2 h in dog. The half-life of radioactivity in plasma was longer in both species.

5. After both routes of administration, radioactivity was rapidly distributed in rat tissues with the highest concentration in liver, fat and gastrointestinal tract. Only traces of radioactivity were detected in the CNS and in rat foetuses.

6. Extensive biliary elimination occurred, and most of the radioactivity (73-95%) was excreted in the faeces after i.v. or oral administration.

7. The compound was extensively metabolized, no significant amount of unchanged drug was excreted in bile or urine.     

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.     

Ketorolac tromethamine absorption, distribution, metabolism, excretion, and pharmacokinetics in animals and humans

Ketorolac tromethamine (KT), a potent non-narcotic analgesic, with cyclooxygenase inhibitory activity, was administered (14C-labeled and unlabeled) intravenously (iv), orally (po), and intramuscularly (im) in solution to humans, cynomolgus monkeys, rabbits, rats, and mice. KT was absorbed rapidly (Tmax less than 1.0 hr) and efficiently (greater than 87%) following po and im doses in all species. The plasma half-life of ketorolac (K) ranged from 1.1 hr (rabbits) to 6.0 hr (humans). The protein binding of K ranged from 72.0% (mouse) to 99.2% (humans). Linear pharmacokinetics of K was observed in the mouse after single oral doses of KT ranging from 0.25 to 16 mg/kg. Radioactivity was excreted predominantly into urine, ranging from 78.9% (mouse) to 102% (monkey) following iv doses. The dose was excreted into urine primarily as K conjugates, K, and p-hydroxy-K in humans. The monkey was similar to humans with respect to kinetics, but did not form the p-hydroxy metabolite. The rabbit was unusual in that it exhibited substantial presystemic metabolism (50%). The rat excreted a much higher percentage of radioactivity into the feces and formed an additional unidentified metabolite. The most comparable species with respect to humans metabolically was the mouse. The metabolism and excretion of K was similar following iv, po, and im doses within each species studied.     

Metabolism and disposition of morpholine in the rat,hamster, and guinea pig

The blood plasma levels and urinary metabolites of morpholine were examined in three rodent species: the Sprague-Dawley rat, the Syrian golden hamster, and the strain II guinea pig. Marked differences were found between the guinea pig and the other two species with respect to plasma levels as well as the metabolism of morpholine. After ip administration of 125 mg/kg [¹⁴C]morpholine (50 μCi) per animal, the blood plasma half-lives in the rat, hamster, and guinea pig were: 115, 120, and 300 min, respectively. In all three species, approximately 80% of the radioactivity was excreted in the urine in 24 hr. However, while nonmetabolized [¹⁴C]morpholine constituted up to 99% of the urinary radioactivity in the rat and hamster, a significant portion of the dose (approximately 20%) appeared in guinea pig urine as N-methylmorpholine-N-oxide. This new metabolite of morpholine was isolated by Sephadex LH-20 chromatography and confirmed by thin-layer chromatography, gas chromatography, and mass spectrometry.     

The metabolism of l-N-benzyl- -methoxy-3-trifluoromethylphenethylamine hydrochloride in the rat, dog, monkey and man

l-N-benzyl-β-methoxy-3-trifluoromethylphenethylamine hydrochloride, an anorectic agent, was administered to rats, dogs, monkeys and man, employing either the ¹⁴C labeled or nonistopic drug. The compound was essentially completely absorbed. A major portion of the dose was excreted during the first 24 hr; however, drug-related material continued to be slowly excreted over a 96-hr collection period.

Urinary excretion of drug-related material, as compared to fecal excretion, was slightly lower in the rat and approximately twice as high in the dog. Urinary excretion in the monkey was in the same range as seen in the dog. Human urinary excretion of dose was comparable to that of the rat. Fecal excretion was not measured in the latter two species. Rat biliary excretion of over 50 % of dose in 24 hr showed the bile to be an important excretion route in this species. Plasma levels of drug-related material were prolonged in all species studied. These levels, when measured in monkeys, remained relatively constant during a 24-hr sampling period. The remaining three species showed plasma parent compound half-lives of approximately 3–4 hr. The desbenzyl metabolite and total drug-related material half-lives were in the range of 7–9 hr.

Drug distribution in tissues was highest in concentration in the vascular organs i.e. liver, lungs, kidneys and spleen. Brain tissue in rats contained only basic drug-related material which was predominantly the desbenzyl metabolite. Only a trace of unchanged parent compound was present. Metabolites, identified by a combination of thin-layer and gas chromatography, by mass spectral and isotope dilution analyses, were trifluoromethyl-O-methylphenethylamine, trifluoromethyl-O-methylmandelic acid, trifluoromethylmandelic acid and trifluoromethylhippuric acid. Conjugation of the desbenzyl metabolite as a glucuronide was found in dog and monkey, indicated in man, but not found in the rat.

Assay methods specific for the drug and the desbenzyl metabolite (gas chromatography) and a nonspecific method which measured the organically bound fluorine of the compound were developed and applied to plasma and urine specimens.     

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.     

The disposition and metabolic fate of 14C-cibenzoline in man

The disposition and metabolic fate of cibenzoline (CBZ) following single oral 153-mg doses of 14C-CBZ succinate were studied in five healthy adult males. The mean maximum plasma radioactivity of 386 ng eq/ml occurred at 2.4 hr after administration. The mean half-life, determined from the 14C plasma concentration and urinary excretion rate data, was 13.1 and 14.8 hr, respectively. The mean maximum CBZ concentration was 196 ng/ml at 1.2 hr post-dose. The mean half-life, determined from the plasma concentration and urinary excretion rate data, was 7.2 and 7.3 hr, respectively. The mean total clearance of radioactivity and CBZ was 300 ml/min and 1224 ml/min, respectively, due to elimination via both renal and nonrenal pathways. The only unconjugated metabolite in the plasma was 4,5-dehydrocibenzoline which, together with other unidentified metabolites, is presumed responsible for the longer observed half-life for total radioactivity. Approximately 75% of the dose was recovered in the urine in the first 24 hr after dosing, 80% of which was present at CBZ and known metabolites. After 6 days, a mean of 85.7% of the dose was excreted in urine and 13.2% in feces. The predominant excreted compound was CBZ (55.7% of the dose) in the 0-72 hr urine. Although several metabolites were identified in urine samples, none were found in substantial amounts relative to the parent drug. Two of these substances showed slight antiarrhythmic activity, whereas the 4,5-dehydro metabolite, representing approximately 4% of radioactivity in urine, was inactive.     

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 and disposition of sulfinalol in laboratory animals

Peak levels of radioactivity in blood occurred 1.0 hr after oral administration of 3H-sulfinalol hydrochloride to rats, dogs, and monkeys. The plasma decay curve for intact sulfinalol in the dog was biphasic, with apparent first-order half-lives of 0.55 and 6.2 hr. Rats excreted 42.5% of the dose in the urine and 31.8% in the feces after 24 hr. Urinary and fecal recovery were 53.8% and 41.2%, respectively, after 10 days for dogs and 57.8% and 38.0%, respectively, after 9 days for monkeys. Free sulfinalol (11.8% of the dose) was the major component in dog feces with lesser amounts of the sulfide and sulfone metabolites, also in the unconjugated form. All metabolites in dog urine were conjugated with glucuronic acid, with sulfinalol (28.5%) and desmethylsulfinalol (8.5%) representing the major constituents, whereas the sulfone and sulfide metabolites were minor ones. Monkey feces contained primarily unconjugated forms of the desmethyl sulfide metabolite (17.0%) and sulfinalol (7.5%); lesser amounts of desmethylsulfinalol and the sulfone metabolite were present. Desmethylsulfinalol (8.7%) and its sulfate (7.0%) and glucuronide (4.0%) conjugates were the major urinary metabolites in the monkey; sulfinalol (1.4%), its glucuronide conjugate (5.1%), the desmethyl sulfide metabolite (and its sulfate conjugate), and the sulfone metabolite were also present.