Excretion of [3H]triptolide and its metabolites in rats after oral administration

Aim： To investigate the routes of elimination and excretion for triptolide recovered in rats.
Methods： After a single oral administration of [3H]triptolide （0.8 mg/kg, 100 μCi/kg） in Sprague Dawley rats, urine and fecal samples were collected for 168 h. To study biliary excretion, bile samples were collected for 24 h through bile duct cannulation. Radioactivity was measured using a liquid scintillation analyzer, and excretion pathway analysis was performed using an HPLC/on-line radioactivity detector.

Results： The total radioactivity recovered from the urine and feces of rats without bile duct ligation ranged from 86.6%–89.1%. Most of the radioactivity （68.6%–72.0%） was recovered in the feces within 72 h after oral administration, while the radioactivity recovered in the urine and bile was 17.1%–18.0% and 39.0%–39.4%, respectively. The HPLC/on-line radiochromatographic analysis revealed that most of the drug-related radioactivity was in the form of metabolites. In addition, significant gender differences in the quantity of these metabolites were found： monohydroxytriptolide sulfates were the major metabolites detected in the urine, feces, and bile of female rats, while only traces of these metabolites were found in male rats.

Conclusion： Radiolabeled triptolide is mainly secreted in bile and eliminated in feces. The absorbed radioactivity is primarily eliminated in the form of metabolites, and significant gender differences are observed in the quantity of recovered metabolites, which are likely caused by the gender-specific expression of sulfotransferases.     

The pharmacokinetics and metabolism of idazoxan in the rat

1. [2'-14C]Idazoxan was rapidly and completely absorbed after its oral administration to rats. 2. After administration of either [2'-14C] or [6,7-3H]idazoxan, radioactivity was taken up by a wide range of tissues and became localized, especially in the organs of metabolism and excretion. Quantitative distribution patterns were route-dependent such that oral dosing resulted in lower radioactivity concentrations in all tissues apart from liver. 3. Clearance of idazoxan (94-144 ml/min per kg) was due mostly to metabolism and was independent of dose. Oral bioavailability in male rats at low oral doses of idazoxan (10 mg/kg) was about 1%, but increased with increasing dose to 23% at 100 mg/kg. Oral bioavailability in female rats was considerably higher than in male rats, at all doses studied. Brain idazoxan levels were in equilibrium with those in plasma, but ten-fold higher. 4. Elimination of radioactivity after administration of 14C-idazoxan was via the urine and the faeces (about 75% and 20% of dose respectively) and occurred essentially in the 24 h period immediately after dosing. By 96 h after dosing, elimination was virtually complete, with less than 0.5% dose remaining in the carcasses. 5. Biotransformation was by hydroxylation at positions 6 and 7 to form phenolic metabolites, which were excreted as glucuronide and sulphate metabolites in urine, but unconjugated in faeces. Other minor metabolic routes were 5-hydroxylation or oxidative degradation of the imidazoline ring, but these pathways were of quantitatively minor importance in the rat.     

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)     

The absorption, tissue distribution and excretion of di-n-octyltin dichloride in rats

In this study the absorption, tissue distribution and excretion of 14C-labeled di-n-octyltin dichloride ([14C]DOTC) in rats were investigated after oral and intravenous (i.v.) administration. Although after i.v. administration with 1.2 mg [14C]DOTC/kg body weight the tissue radioactivity was about 3-4 times higher than after oral administration with 6.3 mg [14C]DOTC/kg body weight, the relative tissue accumulation was found to be the same after the oral and i.v. dosage. The highest amount of radioactivity was found in liver and kidney, and to a lesser degree in adrenal, pituitary and thyroid glands. The lowest activity was recovered from blood and brain. No selective accumulation was observed in thymus, although it has been reported that thymus atrophy is the most sensitive parameter of DOTC toxicity in rats. For all tissues a time dependent decrease in radioactivity was found, except for kidney. The excretion of radioactivity in feces and urine was determined after a single i.v. or oral dose of 1.2 and 2 mg [14C]DOTC, respectively. After i.v. administration most of the radioactivity was excreted in the feces which was characterized by a biphasic excretion pattern. In orally treated rats more than 80% of the radioactivity was already excreted in the feces during the first day after administration. This indicated that only a small part of the DOTC was absorbed, which was calculated to be approximately 20% of the dose. Similar half-life values of 8.3 and 8.9 days were obtained from the fecal excretion of radioactivity after the i.v. and oral administration, respectively. The urinary excretion of radioactivity appeared to be independent of the body burden, since the daily amount of radioactivity excreted in urine was nearly the same independent of the route of administration as well as the time after administration.     

Beta-cyclodextrin reduces bioavailability of orally administered [3H]benzo[a]pyrene in the rat

The excretion and plasma kinetics of total radioactivity were studied following single oral administration of [(3)H]benzo[a]pyrene after multiple oral administration of beta-cyclodextrin at 0, 5, 50, or 500 mg/kg/day. The AUC and C(max) values in male and female rats following administration of [(3)H]benzo[a]pyrene in combination with 5 to 500 mg/kg beta-cyclodextrin were considerably lower than that in rats administered [(3)H]benzo[a]pyrene alone. At all dose levels of beta-cyclodextrin, the excretion of total radioactivity was almost entirely via feces, with <2% recovered in urine, demonstrating either that absorption of the orally administered dose was low or that, for any absorbed material, biliary excretion was the main route of excretion. However, following administration of vehicle, up to 5% of the administered radioactivity was recovered in the urine, suggesting that absorption may have been reduced by the presence of beta-cyclodextrin in the intestine. At all dose levels of beta-cyclodextrin, there was minimal retention of radioactivity in the carcase at the end of the collection period. Beta-cyclodextrin did not affect the apparent terminal half-life of radioactivity. Therefore, the reduced systemic exposure of rats to radioactivity in the presence of beta-cyclodextrin is likely related to a reduced oral bioavailability.     

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.     

Comparative study on the disposition of a new orally active dopamine prodrug, N-(N-acetyl-L-methionyl)-O,O-bis(ethoxycarbonyl)dopamine (TA-870) and dopamine hydrochloride in rats and dogs

The pharmacokinetics of a dopamine derivative, TA-870, and dopamine (DA) after oral administration are compared in rats and dogs. The maximum concentrations of free DA in plasma after oral administration of TA-870 were 150 ng/ml in the rat (30 mg/kg) and 234 ng/ml in the dog (33.5 mg/kg). On the contrary, the maximum plasma concentrations after oral administration of DA at an equimolar dose to TA-870 were 12 ng/ml in the rat (12 mg/kg) and 36 ng/ml in the dog (13.5 mg/kg). The AUC values of free DA in plasma after oral administration of TA-870 (30 or 33.5 mg/kg) were 4-6 times higher than those after DA in both animal species. The peak tissue levels of radioactivity in rats after oral administration of [14C]TA-870 (30 mg/kg) were also 5.5 times higher in the liver and 1-2 times higher in other tissues than those after [14C]DA dose (12 mg/kg). In rats, the main excretion route of radioactivity after oral administration of [14C]TA-870 or DA was via the urine. The total recoveries of radioactivity in the urine and feces were 91-96% of the dose within 24 hr for both compounds. Biliary excretion in rats accounted for 19.8% of the dose of [14C]TA-870 and 12.6% of the dose of [14C]DA within 24 hr. These results demonstrate that TA-870 was well absorbed from the digestive tract, extensively metabolized to dopamine, and proved to be an orally usable dopamine prodrug.     

The metabolic disposition of aprepitant, a substance P receptor antagonist, in rats and dogs.

The absorption, metabolism, and excretion of [14C]aprepitant, a potent and selective human substance P receptor antagonist for the treatment of chemotherapy-induced nausea and vomiting, was evaluated in rats and dogs. Aprepitant was metabolized extensively and no parent drug was detected in the urine of either species. The elimination of drug-related radioactivity, after i.v. or p.o. administration of [14C]aprepitant, was mainly via biliary excretion in rats and by way of both biliary and urinary excretion in dogs. Aprepitant was the major component in the plasma at the early time points (up to 8 h), and plasma metabolite profiles of aprepitant were qualitatively similar in rats and dogs. Several oxidative metabolites of aprepitant, derived from N-dealkylation, oxidation, and opening of the morpholine ring, were detected in the plasma. Glucuronidation represented an important pathway in the metabolism and excretion of aprepitant in rats and dogs. An acid-labile glucuronide of [14C]aprepitant accounted for approximately 18% of the oral dose in rat bile. The instability of this glucuronide, coupled with its presence in bile but absence in feces, suggested the potential for enterohepatic circulation of aprepitant via this conjugate. In dogs, the glucuronide of [14C]aprepitant, together with four glucuronides derived from phase I metabolites, were present as major metabolites in the bile, accounting collectively for approximately 14% of the radioactive dose over a 4- to 24-h period after i.v. dosing. Two very polar carboxylic acids, namely, 4-fluoro-alpha-hydroxybenzeneacetic acid and 4-fluoro-alpha-oxobenzeneacetic acid, were the predominant drug-related entities in rat and dog urine.     

The metabolism and excretion of prochloraz, an imidazole-based fungicide, in the rat.

1. Following oral administration of prochloraz (1-[N-propyl-N-2-(2,4,6-trichlorophenoxy)ethylcarbamoyl]imidazole) at 100 mg/kg body weight to rats, the compound underwent extensive metabolism, the primary route appearing to be opening of the imidazole ring followed by hydrolysis of the alkyl chain. The major metabolites were 2,4,6-trichlorophenoxyacetic acid and 2-(2,4,6-trichlorophenoxy)ethanol, which is present mainly as a glucuronide conjugate. Ring hydroxylation occurred to produce several minor metabolites. No unchanged prochloraz was excreted in the urine. 2. Tissue residues 96 h after dosing were generally less than 1 mg prochloraz equivalents/kg tissue. The highest residues were found in the liver (2.8-5.1 mg prochloraz equivalents/kg tissue) and kidney (1.5-2.1 mg prochloraz equivalents/kg tissue), the principal organs of metabolism and excretion. Residues in female rats were generally slightly higher than those found in males. 3. The metabolites were quantitatively excreted within 96 h, with greater than 50% of the dosed radioactivity being found in the 0-24 h excreta. Urinary excretion accounted for 65% dose in male and 41% in female rats, respectively.     

Metabolism and disposition of the flame retardant plasticizer, tri-p-cresyl phosphate, in the rat

The metabolism and disposition of tri-p-cresyl phosphate (TPCP) were studied in the rat after a single oral administration of [methyl-14C] TPCP. At a dosage of 7.8 mg/kg, most of the administered radioactivity was excreted in the urine (41%) and feces (44%) in 7 days. For 3 days, the expiratory excretion as 14CO2 amounted to 18% of the radioactivity, but was reduced to 3% by treatment of the animal with neomycin. In separate rats, the biliary excretion amounted to 28% of the dose in 24 hr. At a dose of 89.6 mg/kg, the radioactivity was excreted in urine (12%) and feces (77%) in 7 days, and the expired air (6%) in 3 days. At 24, 72, and 168 hr after oral administration, the concentration of radioactivity was relatively high in adipose tissue, liver, and kidney. The major urinary metabolites were p-hydroxybenzoic acid, di-p-cresyl phosphate (DCP), and p-cresyl p-carboxyphenyl phosphate (1coDCP). The biliary metabolites were DCP, 1coDCP, and the oxidized triesters, di-p-cresyl p-carboxyphenyl phosphate (1coTPCP), and p-cresyl di-p-carboxyphenyl phosphate (2coTPCP). The main fecal metabolite was TPCP, and the others were similar to those of bile. Following oral administration, TPCP was absorbed from the intestine, distributed to the fatty tissues, and moderately metabolized to a variety of products of oxidation and dearylation of TPCP, which were then excreted in the urine, feces, bile, and expired air. The intestinal microflora appeared to play an important role in degrading biliary metabolites to 14CO2 through the enterohepatic circulation in rats.     

Mass balance study of [14C] rabeprazole following oral administration in healthy subjects

The study was designed to determine the excretion balance of radiolabeled rabeprazole in urine and feces and to examine the metabolite profile in plasma, urine and feces after a single oral dose of [14C] rabeprazole, preceded by once daily dose of rabeprazole for 7 days. Six healthy subjects were enrolled in this study. The study was a single-center, open-label, multiple-dose, mass-balance study. Each subject received a single 20 mg dose of rabeprazole tablet for 7 days followed by the administration of 20 mg of [14C] rabeprazole as an oral solution after an overnight fast on Day 8. After oral dosing of [14C] rabeprazole, the mean Cmax of total radioactivity was 1,080 +/- 215 ng equivalent/ml with 0.33 +/- 0.13 hours of the mean tmax. The apparent elimination half-life of total [14C] radioactivity was 12.6 +/- 3.4 hours. The total [14C] recovery in urine and feces was 99.8 +/-0.7% by 168 hours after oral administration of [14C] rabeprazole, and mean cumulative [14C] radioactivity excreted in urine was 90.0 +/- 1.7% by 168 hours and 79.8 +/- 2.5% of the radioactivity was excreted in urine within 24 hours. Excretion via feces added to the total by 9.8%. The major radioactive component in the early plasma samples was rabeprazole, however the thioether and thioether carboxylic acid metabolites were the main radioactive components in the later plasma sample. These results support the previous finding that the substantial contribution of the non-enzymatic thioether pathway minimizes the effect of CYP2C19 polymorphism on the inter-individual variation ofplasma clearance of rabeprazole compared with other PPIs. Low levels of the sulfone metabolite were detected only in early plasma samples. No rabeprazole was detected in any urine and feces samples. The main radioactive components in urine were thioether carboxylic acid and mercapturic acid conjugate metabolites, and in the feces, the thioether carboxylic acid metabolite. The administration of [14C] rabeprazole was safe as evidenced by the lack of serious adverse events and the fact that all observed events were mild in intensity. [14C] rabeprazole was rapidly absorbed after oral administration and mostly excreted in urine.     

Metabolism and disposition of moxonidine in Fischer 344 rats.

The metabolism and disposition of moxonidine (4-chloro-5-(imidazolidin-2-ylidenimino)-6-methoxy-2-methylp yrimidine ), a potent central-acting antihypertensive agent, were investigated in F344 rats. After an i.v. or oral administration of 0.3 mg/kg of [(14)C]moxonidine, the maximum plasma concentrations of moxonidine were determined to be 146.0 and 4.0 ng/ml, respectively, and the elimination half-lives were 0.9 and 1.1 h, respectively. The oral bioavailability of moxonidine was determined to be 5.1%. The metabolic and elimination profiles of moxonidine were determined after an oral administration of 5 mg/kg of [(14)C]moxonidine. More than fifteen phase I and phase II metabolites of moxonidine were identified in the different biological matrices (urine, plasma, and bile). Oxidative metabolism of moxonidine leads to the formation of hydroxymethyl moxonidine and a carboxylic acid metabolite as the major metabolites. Several GSH conjugates, cysteinylglycine conjugates, cysteine conjugates, and a glucuronide conjugate were also identified in rat bile samples. The radiocarbon was eliminated primarily by urinary excretion in rats, with 59.5% of total radioactivity recovered in the urine and 38.4% recovered in the feces within 120 h. In bile duct-cannulated rats, about 39.7% of the radiolabeled dose was excreted in the urine, 32.6% excreted in the bile, and approximately 2% remained in the feces. The results from a quantitative whole body autoradiography study indicate that radiocarbon associated with [(14)C]moxonidine and/or its metabolites was widely distributed to tissues, with the highest levels of radioactivity observed in the kidney and liver. In summary, moxonidine is well absorbed, extensively metabolized, widely distributed into tissues, and rapidly eliminated in rats after oral administration.     

Absorption,Distribution, Metabolism,and Excretion of N-Octylbicycloheptene Dicarboximide (MGK 264) Administered Orally to Rats

Abstract

Experiments were conducted in four groups of rats to determine the absorption, distribution, metabolism, and excretion (ADME) patterns following oral administration of [hexyl-1-¹⁴C] N-octylbicycloheptene dicarboximide (MGK 264).

Ten rats (five males and five females) were used in each of the four experiments. Fasted rats were administered fhexyl-1-¹⁴C] MGK 264 at a single oral dose of 100 mg/kg, at a single oral dose of 1000 mg/kg, and at a daily oral dose of 100 mg/kg of nonradiolabeled compound for 14 days followed by a single dose of ¹⁴C-labeled compound at 100 mg/kg. Rat blood kinetics were determined in the fourth group following a single oral dose of 100 mg/kg. Each animal was administered 18-30 μCi radioactivity.

Urine and feces were collected for all groups at predetermined time intervals. Seven days after dose administration, the rats were euthanized and selected tissues and organs were harvested. Samples of urine, feces, and tissues were subsequently analyzed for ¹⁴C content.

In the blood kinetics study, radioactivity peaked at approximately 4 h for the males and 6 h for the females. The decline of radioactivity from blood followed a monophasic elimination pattern. The half-life of blood radioactivity was approximately 8 h for males and 6 h for females.

Female rats excreted 71.45-73.05% of the radioactivity in urine and 20.87-25.28% in feces, whereas male rats excreted 49.49-63.49% of the administered radioactivity in urine and 31.76-46.67% in feces. Total tissue residues of radioactivity at 7 days ranged from 0.13 to 0.43% of the administered dose for all dosage regimens. The only tissues with ¹⁴C residues consistently higher than that of plasma were the liver, stomach, intestines, and carcass. The total mean recovered radioactivity of the administered dose in the studies ranged between 93.1 and 97.4%. No parent compound was detected in the urine.

Four major metabolites and one minor metabolite were isolated from the urine by high-performance liquid chromatography (HPLC) and identified by gas chromatography/mass spectometry (GC/MS) and liquid chromatography/mass spectrometry (LC/MS). The four major metabolites were shown to be carboxylic acids produced by either ω-1 oxidation or β-oxidation of the side chain and oxidation of the norbornene ring double bond. The minor metabolite was the carboxylic acid of the intact norbornene ring.

The gender of the animals affected the rate, route of excretion, and metabolic profile. The urinary excretion rate was faster in females than in males and the amount excreted was also greater in female rats.     

Pharmacokinetics, tissue distribution, metabolism, and excretion of celecoxib in rats.

The pharmacokinetics, tissue distribution, metabolism, and excretion of celecoxib, 4-[5-(4-methylphenyl)-3-(trifluoromethyl)-1H-pyrazol-1-yl] benzenesulfonamide, a cyclooxygenase-2 inhibitor, were investigated in rats. Celecoxib was metabolized extensively after i.v. administration of [(14)C]celecoxib, and elimination of unchanged compound was minor (less than 2%) in male and female rats. The only metabolism of celecoxib observed in rats was via a single oxidative pathway. The methyl group of celecoxib is first oxidized to a hydroxymethyl metabolite, followed by additional oxidation of the hydroxymethyl group to a carboxylic acid metabolite. Glucuronide conjugates of both the hydroxymethyl and carboxylic acid metabolites are formed. Total mean percent recovery of the radioactive dose was about 100% for both the male rat (9.6% in urine; 91.7% in feces) and the female rat (10.6% in urine; 91.3% in feces). After oral administration of [(14)C]celecoxib at doses of 20, 80, and 400 mg/kg, the majority of the radioactivity was excreted in the feces (88-94%) with the remainder of the dose excreted in the urine (7-10%). Both unchanged drug and the carboxylic acid metabolite of celecoxib were the major radioactive components excreted with the amount of celecoxib excreted in the feces increasing with dose. When administered orally, celecoxib was well distributed to the tissues examined with the highest concentrations of radioactivity found in the gastrointestinal tract. Maximal concentration of radioactivity was reached in most all tissues between 1 and 3 h postdose with the half-life paralleling that of plasma, with the exception of the gastrointestinal tract tissues.     

Pharmacokinetics of nimodipine. I. Communication: absorption, concentration in plasma and excretion after single administration of [14C]nimodipine in rat, dog and monkey

Studies on absorption, plasma concentrations and excretion with (+/-)isopropyl-2-methoxyethyl-1,4-dihydro-2,6-dimethyl-4-(3-nitrophenyl) -3,5-pyridinedicarboxylate (nimodipine, Bay e 9736, Nimotop) have been conducted in rat, dog and monkey using the carbon-14-labelled substance and a wide range of doses (0.05-10 mg/kg) administered via different routes (intravenous, oral, intraduodenal). Nimodipine was well absorbed in all species. Peak plasma concentrations of radioactivity were determined 28-40 min (male rat), 60 min (female rat), about 3 h (dog) and 7 h (monkey) after administration. Dependent on the observation period (24-216 h) terminal half-lives for the elimination of radioactivity from plasma ranging between 4.6 h (female rat) and 157 h (dog) were observed. Comparing the AUC, the concentration of unchanged [14C]nimodipine in plasma represented only a small (maximally 37% in dogs after i.v. dose) to negligible (about 1%, monkey after oral dosing) part of the total radioactivity. Excretion of radioactivity via feces and urine was rapid in all species after both oral and intravenous dosing. Fecal (biliary) excretion was the major excretory route in rat and dog. The monkeys excreted about 40 to 50% via the urine. Residues in the body never exceeded 1.5% of the dose. [14C]nimodipine and/or its radiolabelled metabolites were secreted in milk of orally dosed lactating rats. Binding of [14C]nimodipine to plasma proteins of rat and dog was about 97%.     

Metabolism, pharmacokinetics, and excretion of a nonpeptidic substance P receptor antagonist, ezlopitant, in normal healthy male volunteers: characterization of polar metabolites by chemical derivatization with dansyl chloride.

The excretion, biotransformation, and pharmacokinetics of ezlopitant [(2-benzhydryl-1-aza-bicyclo[2.2.2]oct-3-yl)-(5-isopropyl-2-methoxy-benzyl)-amine], a substance P receptor antagonist, were investigated in healthy male volunteers after oral administration of a single 200-mg (approximately 93 microCi/subject) dose of [(14)C]ezlopitant. The total recovery of administered radioactive dose was 82.8 +/- 5.1, with 32.0 +/- 4.2% in the urine and 50.8 +/- 1.4% in the feces. Mean observed maximal serum concentrations for ezlopitant and total radioactivity were achieved at approximately 2 h after oral administration; thus, ezlopitant was rapidly absorbed. Ezlopitant was extensively metabolized in humans, since no unchanged drug was detected in urine and feces. The major pathway of ezlopitant in humans was the result of the oxidation of the isopropyl side chain to form the omega-hydroxy and omega-1-hydroxy (M16) metabolites. M16 and omega,omega-1-dihydroxy (1,2-dihydroxy, M12) were identified as the major circulating metabolites accounting for 64.6 and 15.4% of total circulating radioactivity, respectively. In feces, the major metabolite M14 was characterized as the propionic acid metabolite and formed by further oxidation of the omega-hydroxy metabolite. The urinary metabolites were the result of cleaved metabolites caused by oxidative dealkylation of the 2-benzhydryl-1-aza-bicyclo[2.2.2]oct-3-yl moiety. The metabolites (M1A, M1B, and M4), approximately 34% of the total radioactivity in urine, were identified as benzyl amine derivatives. These were polar metabolites that were further characterized using the reaction with dansyl chloride to derivatize the primary amines and phenol moieties to less polar analytes. The other metabolites were the result of O-demethylation, dehydrogenation of the isopropyl group, and oxidation on the quinuclidine moiety.     

Absorption, excretion, and metabolism of the endothelin receptor antagonist bosentan in healthy male subjects.

The absorption, excretion, and metabolism of the endothelin receptor antagonist bosentan was investigated in healthy male subjects by administration of 14C-labeled compound. Four subjects received a single oral dose of 500 mg of bosentan (3.7 MBq), and four other subjects received a single i.v. dose of 250 mg of bosentan (3.7 MBq). Radioactivity and concentrations of bosentan and its metabolites were measured in plasma, urine, and feces samples. More than 97% of drug-related material was recovered on average within 3.5 days after oral dosing and within 5 days after i.v. dosing. More than 90% of radioactivity was found in feces after both oral and i.v. dosing. Most of the radioactivity in urine and feces represented bosentan and three metabolites. Ro 48-5033, the major metabolite in plasma, urine, and feces, is the result of hydroxylation at the t-butyl group of bosentan. The two other metabolites Ro 47-8634 and Ro 64-1056 represent minor metabolite species. Ro 47-8634 is the product of O-demethylation of the phenolic methyl ester, and Ro 64-1056 is generated by both demethylation and hydroxylation. The radioactivity in plasma could almost entirely be attributed to bosentan and the two metabolites Ro 48-5033 and Ro 47-8634, whereby both metabolites exhibited much lower plasma levels than bosentan. Hepatic metabolism followed by biliary excretion of the metabolites apparently represents the major pathway of elimination for bosentan in humans.     

Influence of a purified diet and route of administration on the metabolism and disposition of estradiol in B6C3F1 mice

The metabolism and disposition of [6,7-3H]estradiol ([3H]E2) given by gavage (po) or intravenously (iv) were examined in female B6C3F1 mice fed either the purified AIN-76A (AIN) or cereal-based NIH-07 (NIH) diet for a period of 8 weeks prior to treatment with E2. Initially, 40.6 Ci of [3H]E2 was given iv to each mouse. Subsequently, 45.6 Ci of [3H]E2 was given po to the same mice. Samples of blood, urine, and feces were obtained during a 48-hr period after each dosing. Total radioactivity was determined for each sample. Urine and plasma samples were analyzed by HPLC, and the radiolabeled metabolites were tentatively identified and quantified. Statistical comparisons were made of the effects of diet, route of administration, and interactions among groups. Analysis revealed: 1) greater fecal than urinary excretion of radioactivity regardless of route of administration or diet fed, 2) more radioactivity excreted in the urine of AIN-fed than in NIH-fed mice, significantly different only after iv administration (p less than 0.02), and 3) a greater feces:urine ratio of excreted radioactivity following iv than po administration and from NIH-than AIN-fed mice. Metabolite profiles showed: 1) no differences in urine due to route of administration, 2) estriol conjugates dominated urinary metabolites, 3) accumulation of radioactive material in plasma that apparently was tritiated water, with more rapid accumulation of tritiated water after po than iv administration, 4) relatively more plasma estradiol-17-glucuronide, estriol-3-sulfate, and estriol in po- than in iv-treated mice, 5) estradiol-3, 17-sulfate in plasma of iv- but not po-treated mice.(ABSTRACT TRUNCATED AT 250 WORDS)     

Disposition and biotransformation of the estrogenic isoflavone daidzein in rats.

Daidzein is an estrogenic isoflavone present in many plants and therefore consumed in relatively high doses by humans. Daidzein has a low affinity for the estrogen receptor (3 orders of magnitude lower than estradiol) and has been demonstrated to have estrogenic effects in rodents after administration of high doses. We have studied the disposition and biotransformation of daidzein in rats fed a diet low in isoflavone content. Four male and four female Fischer 344 rats were orally administered 100 mg/kg daidzein; excreted urine and feces were collected for 96 h and unchanged daidzein as well as formed metabolites were quantified by HPLC. In urine of male rats, daidzein, daidzein-glucuronide, and daidzein-sulfate were excreted; in females, only unchanged daidzein and daidzein-glucuronide were present. Total urinary excretion of daidzein accounted for < 10% of dose in both males and females. The major pathway of daidzein elimination was excretion of unchanged daidzein with feces. Reductive daidzein-metabolites likely formed by intestinal microflora (equol, O-desmethylangolensin) were excreted with feces in small amounts (< 5% of dose). Excretion of daidzein and metabolites with urine and feces was rapid with elimination half-lives of less than 12 h; daidzein concentrations in urine and feces were below the limit of detection 36 h after daidzein administration. The results suggest that daidzein is only poorly absorbed from the gastrointestinal tract in rodents. Absorbed daidzein is rapidly eliminated both unchanged and as conjugates with urine. The inefficient absorption of daidzein from the gastrointestinal tract and the rapid excretion may explain the weak estrogenicity of daidzein seen in vivo in rodents when compared to other estrogenic chemicals with comparatively low affinity to the estrogen receptor.     

Disposition and metabolism of 2-bromo-4,6-dinitroaniline in the male F344 rat

The disposition of [14C]-2-bromo-4,6-dinitroaniline (BDNA) was studied in male F344 rats following oral or intravenous (iv) administration. The gastrointestinal absorption of BDNA was nearly complete and was not affected by dose in the range (10-100 mumol/kg body weight) studied. Following either oral or iv administration, BDNA was rapidly distributed throughout the tissues and showed no marked affinity for any particular tissue. Clearance of [14C]BDNA-derived radioactivity from various tissues was rapid and was best described by two-component decay curves. The whole-body half-life of BDNA was approximately 7 h. Within 72 h, clearance of [14C]BDNA-derived radioactivity from the body was 98% complete. [14C]BDNA was rapidly cleared by metabolism to 13 metabolites, which were excreted in urine (62%) and feces (33%). Most (66%) of the urinary radioactivity was excreted in the form of sulfate conjugates of two metabolites of BDNA; excretion of unmetabolized BDNA was minimal (less than 2%). Biliary excretion of [14C]BDNA was significant; however, some of this BDNA-derived radioactivity underwent enterohepatic circulation and was subsequently excreted in urine. Results of this study indicate that, if metabolism is a detoxification process, the rapid metabolism and excretion of this compound should minimize the likelihood of chronic toxicity from repeated exposure to BDNA beyond that predicted by data from acute or short-term exposures.