Comparative metabolism of radiolabeled muraglitazar in animals and humans by quantitative and qualitative metabolite profiling.

Muraglitazar (Pargluva), a dual alpha/gamma peroxisome proliferator-activated receptor (PPAR) activator, has both glucose- and lipid-lowering effects in animal models and in patients with diabetes. This study describes the in vivo and in vitro comparative metabolism of [(14)C]muraglitazar in rats, dogs, monkeys, and humans by quantitative and qualitative metabolite profiling. Metabolite identification and quantification methods used in these studies included liquid chromatography/mass spectrometry (LC/MS), LC/tandem MS, LC/radiodetection, LC/UV, and a newly described mass defect filtering technique in conjunction with high resolution MS. After oral administration of [(14)C]muraglitazar, absorption was rapid in all species, reaching a concentration peak for parent and total radioactivity in plasma within 1 h. The most abundant component in plasma at all times in all species was the parent drug, and no metabolite was present in greater than 2.5% of the muraglitazar concentrations at 1 h postdose in rats, dogs, and humans. All metabolites observed in human plasma were also present in rats, dogs, or monkeys. Urinary excretion of radioactivity was low (<5% of the dose) in all intact species, and the primary route of elimination was via biliary excretion in rats, monkeys, and humans. Based on recovered doses in urine and bile, muraglitazar showed a very good absorption in rats, monkeys, and humans. The major drug-related components in bile of rats, monkeys, and humans were glucuronides of muraglitazar and its oxidative metabolites. The parent compound was a minor component in bile, suggesting extensive metabolism of the drug. In contrast, the parent drug and oxidative metabolites were the major components in feces, and no glucuronide conjugates were found, suggesting that glucuronide metabolites were excreted in bile and hydrolyzed in the gastrointestinal tract. The metabolites of muraglitazar resulted from both glucuronidation and oxidation. The metabolites in general had greatly reduced activity as PPARalpha/gamma activators relative to muraglitazar. In conclusion, muraglitazar was rapidly absorbed, extensively metabolized through glucuronidation and oxidation, and mainly eliminated in the feces via biliary excretion of glucuronide metabolites in all species studied. Disposition and metabolic pathways were qualitatively similar in rats, dogs, monkeys, and humans.     

Metabolism and excretion of atorvastatin in rats and dogs.

Atorvastatin (AT) is a second-generation potent inhibitor of 3-hydroxy-3-methylglutaryl-CoA reductase, clinically approved for lowering plasma cholesterol. Using a mixture of [D(5)/D(0)] AT and/or [(14)C]AT, the metabolic fate and excretion of AT were examined in rats and dogs following single and multiple oral doses. Limited biliary recycling was examined in one dog after a single dose of AT. AT-derived metabolites in bile samples were identified by metabolite screening of the [D(5)/D(0)] AT molecular clusters using tandem mass spectrometry. Bile was a major route of [(14)C] drug-derived excretion, accounting for 73 and 33% of the oral dose in the rat and dog, respectively. The remaining radioactivity was recovered in the feces; only trace amounts were excreted in urine. Radioactive components identified in rat and dog bile were the para- and ortho-hydroxy metabolites, a glucuronide conjugate of ortho-hydroxy AT, and unchanged AT. Two minor radioactive components were identified as beta-oxidation products of AT with one confirmed as a beta-oxidized AT derivative. The reappearance of AT and major metabolites in bile from a dog administered a sample of its previously excreted bile indicated biliary recycling is an important component in AT metabolism. Multiple dose administration in rats did not alter biliary metabolic profiles. Rat and dog plasma profiles after multiple dose administration were similar and showed no additional metabolites not found in bile. Examination of rat and dog bile and plasma indicates that AT primarily undergoes oxidative metabolism.     

The absorption, distribution, metabolism and excretion of rofecoxib, a potent and selective cyclooxygenase-2 inhibitor, in rats and dogs.

Absorption, distribution, metabolism, and excretion studies were conducted in rats and dogs with rofecoxib (VIOXX, MK-0966), a potent and highly selective inhibitor of cyclooxygenase-2 (COX-2). In rats, the nonexponential decay during the terminal phase (4- to 10-h time interval) of rofecoxib plasma concentration versus time curves after i.v. or oral administration of [(14)C]rofecoxib precluded accurate determinations of half-life, AUC(0-infinity) (area under the plasma concentration versus time curve extrapolated to infinity), and hence, bioavailability. After i.v. administration of [(14)C]rofecoxib to dogs, plasma clearance, volume of distribution at steady state, and elimination half-life values of rofecoxib were 3.6 ml/min/kg, 1.0 l/kg, and 2.6 h, respectively. Oral absorption (5 mg/kg) was rapid in both species with C(max) occurring by 0.5 h (rats) and 1.5 h (dogs). Bioavailability in dogs was 26%. Systemic exposure increased with increasing dosage in rats and dogs after i.v. (1, 2, and 4 mg/kg), or oral (2, 5, and 10 mg/kg) administration, except in rats where no additional increase was observed between the 5 and 10 mg/kg doses. Radioactivity distributed rapidly to tissues, with the highest concentrations of the i.v. dose observed in most tissues by 5 min and by 30 min in liver, skin, fat, prostate, and bladder. Excretion occurred primarily by the biliary route in rats and dogs, except after i.v. administration of [(14)C]rofecoxib to dogs, where excretion was divided between biliary and renal routes. Metabolism of rofecoxib was extensive. 5-Hydroxyrofecoxib-O-beta-D-glucuronide was the major metabolite excreted by rats in urine and bile. 5-Hydroxyrofecoxib, rofecoxib-3',4'-dihydrodiol, and 4'-hydroxyrofecoxib sulfate were less abundant, whereas cis- and trans-3,4-dihydro-rofecoxib were minor. Major metabolites in dog were 5-hydroxyrofecoxib-O-beta-D-glucuronide (urine), trans-3, 4-dihydro-rofecoxib (urine), and 5-hydroxyrofecoxib (bile).     

HPLC-NMR with severe column overloading: fast-track metabolite identification in urine and bile samples from rat and dog treated with [14C]-ZD6126

The subject of this study was the determination of the major urinary and biliary metabolites of [(14)C]-ZD6126 following i.v. administration to female and male bile duct cannulated rats at 10 mg/kg and 20 mg/kg, respectively, and male bile duct cannulated dogs at 6 mg/kg by HPLC-NMR spectroscopy. ZD6126 is a phosphorylated pro-drug, which is rapidly hydrolysed to the active metabolite, ZD6126 phenol. The results presented here demonstrate that [(14)C]-ZD6126 phenol is subsequently metabolised extensively by male dogs and both, male and female rats. Recovery of the dose in bile and urine was determined utilising the radiolabel, revealing biliary excretion as the major route of excretion (93%) in dog, with the majority of the radioactivity recovered in both biofluids in the first 6 h. In the rat, greater than 92% recovery was obtained within the first 24 h. The major route of excretion was via the bile 51-93% within the first 12 h. The administered phosphorylated pro-drug was not observed in any of the excreta samples. Metabolite profiles of bile and urine samples were determined by high performance liquid chromatography with radiochemical detection (HPLC-RAD), which revealed a number of radiolabelled components in each of the biofluids. The individual metabolites were subsequently identified by HPLC-NMR spectroscopy and HPLC-MS. In the male dog, the major component in urine and bile was the [(14)C]-ZD6126 phenol glucuronide, which accounted for 3% and 77% of the dose, respectively. [(14)C]-ZD6126 phenol was observed in urine at 1% of dose, but was not observed in bile. A sulphate conjugate of demethylated [(14)C]-ZD6126 phenol was identified in bile by HPLC-NMR and confirmed by HPLC-MS. In the rat, the bile contained two major radiolabelled components. One was identified as the [(14)C]-ZD6126 phenol glucuronide, the other as a glucuronide conjugate of demethylated [(14)C]-ZD6126 phenol. However, a marked difference in the proportions of these two components was observed between male and female rats, either due to a sex difference in metabolism or a difference in dose level. The glucuronide conjugate of the demethylated [(14)C]-ZD6126 phenol was present at higher concentration in the bile of male rats (4-34%), while the phenol glucuronide was present at higher concentration in the bile of female rats (8-70%) over a 0-6 h collection period. A third component was only observed in the bile samples (0-6 h and 6-12 h) of male rats. This was identified as being the same sulphate conjugate of demethylated [(14)C]-ZD6126 phenol as the one observed in dog bile. The rat urines contained two main metabolites in greatly varying concentrations, namely the demethylated [(14)C]-ZD6126 phenol glucuronide and the glucuronide of [(14)C]-ZD6126 phenol. Again, the differences in relative amounts between male and female rats were observed, the major metabolite in the urines from male rats being the demethylated [(14)C]-ZD6126 phenol (0-17% in 0-24 h), whilst the phenol glucuronide, accounting for 0.5-50% of the dose over 0-24 h, was the major metabolite in females. Methanolic extracts of the pooled biofluid samples were submitted for HPLC-NMR for the quick identification of the major metabolites. Following a single injection of the equivalent of 6-28 ml of the biofluids directly onto the HPLC-column with minimal sample preparation, the metabolites could be largely successfully isolated. Despite severe column overloading, the major metabolites of [(14)C]-ZD6126 could be positively identified, and the results are presented in this paper.     

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.     

Excretion and metabolism of flunarizine in rats and dogs

The excretion and metabolism of (E)-1-[bis(4-fluorophenyl)methyl]-4-(3-phenyl-2-propenyl)piperazine dihydrochloride (flunarizine hydrochloride, R 14 950, Sibelium) were studied after single oral doses in rats and dogs, using tritium-labelled as well as 14C-labelled drug. Flunarizine was well absorbed in both species. The mass balance for the unchanged drug and its major metabolites in urine, bile and faeces, as estimated with radio-HPLC, ALLOWED an explanation of the differences observed for the excretion pattern of the radioactivity in flunarizine-14C and flunarizine-3H dosed rats, and in male and female rats. Main metabolic pathway in male rats was the oxidative N-dealkylation resulting in bis(4-fluorophenyl)methanol and a number of complementary metabolites of the cinnamylpiperazine moiety, of which hippuric acid was the main one. In female rats and male dogs, however, hydroxy-flunarizine was the main metabolite, resulting from the aromatic hydroxylation of the phenyl ring of the cinnamyl moiety. Enterohepatic circulation of bis(4-fluorophenyl)methanol and hydroxy-flunarizine was proved by "donor-acceptor" coupling in rats; in bile and urine, these two metabolites were present mainly as glucuronides. The glucuronide of hydroxy-flunarizine was also the main plasma metabolite in dogs.     

Species differences in the elimination of a peroxisome proliferator-activated receptor agonist highlighted by oxidative metabolism of its acyl glucuronide.

A species difference was observed in the excretion pathway of 2-[[5,7-dipropyl-3-(trifluoromethyl)-1,2-benzisoxazol-6-yl]oxy]-2-methylpropanoic acid (MRL-C), an alpha-weighted dual peroxisome proliferator-activated receptor alpha/gamma agonist. After intravenous or oral administration of [14C]MRL-C to rats and dogs, radioactivity was excreted mainly into the bile as the acyl glucuronide metabolite of the parent compound. In contrast, when [14C]MRL-C was administered to monkeys, radioactivity was excreted into both the bile and the urine as the acyl glucuronide metabolite, together with several oxidative metabolites and their ether or acyl glucuronides. Incubations in hepatocytes from rats, dogs, monkeys, and humans showed the formation of the acyl glucuronide of the parent compound as the major metabolite in all species. The acyl glucuronide and several hydroxylated products, some which were glucuronidated at the carboxylic acid moiety, were observed in incubations of MRL-C with NADPH- and uridine 5'-diphosphoglucuronic acid-fortified liver microsomes. However, metabolism was more extensive in the monkey microsomes than in those from the other species. When the acyl glucuronide metabolite of MRL-C was incubated with NADPH-fortified liver microsomes, in the presence of saccharo-1,4-lactone, it underwent extensive oxidative metabolism in the monkey but considerably less in the rat, dog, and human liver microsomes. Collectively, these data suggested that the oxidative metabolism of the acyl glucuronide might have contributed to the observed in vivo species differences in the metabolism and excretion of MRL-C.     

Biliary and renal excretion,hepatic metabolism,and hepatic subcellular distribution of metronidazole in the rat

We studied the biliary and renal excretion, hepatic metabolism, and hepatic subcellular distribution of [¹⁴C]metronidazole in bile fistula rats. An average of 71.1 per cent of an intraduodenal or intravenous dose of [¹⁴C]metronidazole was excreted in 24 hr, 23.9 per cent in bile and 47.6 per cent in urine. Renal pedicle ligation caused a 150 per cent increase in biliary excretion of label, whereas phenobarbital pretreatment had no effect. The majority of label in bile and urine was associated with a polar derivative, tentatively identified by thin-layer chromatography and enzymatic hydrolysis as the monoglucuronide conjugate of metronidazole. After intraduodenal administration of purified conjugated [¹⁴C]metronidazole to rats with ligated renal pedicles, only a small amount of label (12.6 per cent of dose in 24 hr) appeared in bile. Growth inhibition studies showed the glucuronide conjugate to be devoid of antimicrobial activity against a metronidazole-sensitive organism, Tritrichomonas foetus. Uptake studies indicated that these organisms were incapable of concentrating conjugated metronidazole. Fractionation of rat liver homogenates by differential centrifugation after intravenous [¹⁴C]metronidazole showed that 90 per cent of label present in liver was in the non-particulate fraction. Our results in rats indicate that metronidazole undergoes an enterohepatic circulation and that the liver plays a major role in the metabolism and excretion of this compound.     

Disposition and metabolism of TAK-438 (vonoprazan fumarate), a novel potassium-competitive acid blocker,in rats and dogs

1.?Following oral administration of [¹⁴C]TAK-438, the radioactivity was rapidly absorbed in rats and dogs. The apparent absorption of the radioactivity was high in both species.

2.?After oral administration of [¹⁴C]TAK-438 to rats, the radioactivity in most tissues reached the maximum at 1-hour post-dose. By 168-hour post-dose, the concentrations of the radioactivity were at very low levels in nearly all the tissues. In addition, TAK-438F was the major component in the stomach, whereas TAK-438F was the minor component in the plasma and other tissues. High accumulation of TAK-438F in the stomach was observed after oral and intravenous administration.

3.?TAK-438F was a minor component in the plasma and excreta in both species. Its oxidative metabolite (M-I) and the glucuronide of a secondary metabolite formed by non-oxidative metabolism of M-I (M-II-G) were the major components in the rat and dog plasma, respectively. The glucuronide of M-I (M-I-G) and M-II-G were the major components in the rat bile and dog urine, respectively, and most components in feces were other unidentified metabolites.

4.?The administered radioactive dose was almost completely recovered. The major route of excretion of the drug-derived radioactivity was via the feces in rats and urine in dogs.     

Blood level, metabolism and excretion of [14C]-brotizolam in mice

Blood level, metabolite pattern and excretion of [14C]-brotizolam, a hypnotic drug, were studied in mice following oral administration. [14C]-Brotizolam was rapidly absorbed which was indicated by a Tmax of the blood level of 0.5 h. Radioactive compounds were eliminated from the blood with a half-life of 5.6 h. Total excretion of radioactivity, the renal portion of which was 22.4%, was complete after 4 days. [14C]-Brotizolam was almost completely metabolized. Using TLC, HPLC and radioactivity measurement, the main metabolite in bile, urine and plasma was found to be brotizolam hydroxylated at the methyl group. Other major metabolites were brotizolam hydroxylated at the diazepine ring and a combination of both hydroxylations. In the bile, all metabolites were conjugated. The metabolism of brotizolam in mice is similar to that in dogs, monkeys and man but not in rats.     

Investigation of the unique metabolic fate of ethyl (6R)-6- [N- (2-chloro-4-fluorophenyl) sulfamoyl] cyclohex-1-ene-1-carboxylate (TAK-242) in rats and dogs using two types of 14C-labeled compounds having different labeled positions

The pharmacokinetics of TAK-242 (ethyl (6R)-6- [N-(2-chloro-4-fluorophenyl)sulfamoyl]cyclohex-1-ene-1-carboxylate, CAS 243984-11-4) and its metabolites were investigated in rats and dogs after intravenous (i.v.) dosing of TAK-242 using two types of radiolabeled TAK-242: [phenyl ring-U-14C]TAK-242 and [cyclohexene ring-U-14C]TAK-242. The phenyl ring moiety of TAK-242 yielded 2-chloro-4-fluoroaniline, M-I, and M-I was further acetylated and conjugated to form M-II and the glucuronide (M-I-G), respectively. M-I was also converted to M-III and M-IV by hydroxylation and subsequent sulfate conjugation. Meanwhile, the cyclohexene ring moiety of TAK-242 was metabolized to glutathione conjugate, M-SG, followed by further metabolism of M-SG to form cysteine conjugate (M-Cys) and mercapturic acid conjugate (M-Mer). After i.v. injection of [phenyl ring-U-14C]TAK-242 to rats and dogs, the 14C concentrations in dogs declined slowly with a half-life of about 1 week although that in rats was about 6 h. The predominant components in the plasma of rats and dogs were M-I-G and M-III, respectively. After i.v. injection of [cyclohexene ring-U-14C]TAK-242 to rats and dogs, 14C-components unextractable by organic solvents were observed in the plasma. These results indicated two unique metabolic fates of TAK-242. The phenyl ring moiety of TAK-242 showed species differences between rats and dogs in the metabolism and excretion kinetics and the cyclohexene ring moiety of TAK-242 showed potential for covalent binding to endogenous components such as plasma proteins.     

Absorption, distribution, metabolism and excretion of YM466, a novel factor Xa inhibitor, in rats

YM466 is a novel factor Xa inhibitor for the treatment of thrombosis. The absorption, distribution, metabolism and excretion of YM466 were investigated in male Fisher rats after a single oral administration. YM466 was absorbed rapidly from all segments of the gastrointestinal tract except the stomach. After oral dosing, the plasma concentration of (14)C-YM466 reached a maximum within 0.5 h, and declined rapidly with an elimination half-life of 0.64 h. The unchanged YM466 accounted for almost all of its radioactivity, suggesting a minimal metabolism in rats. This was also supported by the finding that no metabolites were observed in bile and urine after oral dosing of (14)C-YM466. The distribution of (14)C-YM466 in tissue was evaluated and the liver and kidney were the organs with radioactivity concentrations consistently higher than that of plasma. Cumulative biliary and urinary excretion of radioactivity in bile duct-cannulated rats was 29.5% and 7.6%, respectively, indicating prominent excretion into bile after oral dosing. This was consistent with the finding that 76.1% and 25.2% of radioactivity dosed were excreted to faeces and urine, respectively, after i.v. dosing. These results suggest that YM466 was rapidly absorbed and then subjected to biliary excretion with a minimal metabolism after oral dosing to rats.     

Disposition and metabolism of [14C]-amezinium metilsulfate in rats

Disposition and metabolism of [14C]-amezinium metilsulfate (4-amino-6-methoxy-1-phenylpyridazinium methylsulfate, Risumic) were systematically studied in rats after intravenous (5 mg/kg) or oral (20, 100 mg/kg) administration. After oral administration at 20 mg/kg, blood level reached the maximum (Cmax) of 0.65 microgram eq/ml at 3 h (tmax) and decreased with t1/2 of 8.1 h. Levels in plasma and most tissues elevated to the Cmax at 3 h. The liver level was the highest (61 times as high as plasma level) of all examined tissues. Most tissue levels decreased thereafter essentially in parallel with plasma levels. The findings by whole-body autoradiography essentially agreed with those by radiometry. In lactating rats, milk levels were virtually similar to plasma levels. [14C]-Amezinium metilsulfate radioactivity in fetus and fetal blood was around 0.3 microgram eq/g, being about 1/10 level of maternal plasma level. About 24, 72 and 42% were excreted in urine, feces and bile, respectively. Re-absorption of biliary metabolites accounted for about 31%, being about 13% of orally given [14C]-amezinium metilsulfate. Plasma and aorta contained unchanged amezinium and glucuronide of hydroxyl amezinium MIII. In the brain, the major metabolite was O-demethyl amezinium MV and unchanged drug was not detected. Urinary metabolites were largely MIII glucuronide and the unchanged drug. Biliary metabolite was found composed mostly from MIII glucuronide. In feces, MIII and the unchanged amezinium were found. MIII and its glucuronide were novel metabolites which were identified by thin-layer chromatography and mass spectrometry.     

Metabolic fate of the new angiotensin-converting enzyme inhibitor imidapril in animals. 5th communication: isolation and identification of metabolites of imidapril in rats, dogs, and monkeys.

The metabolism of imidapril hydrochloride ((-)-(4S)-3-[(2S)-2-[[(1S)-1-ethoxycarbonyl-3-phenylpropyl]amino] propionyl]-1-methyl-2-oxoimidazolidine-4-carboxylic acid hydrochloride, imidapril, TA-6366, CAS 89396-94-1) was studied in rats and dogs after oral or intravenous administration of [N-methyl-14C]-imidapril or [alanine-3-14C]-imidapril, and in monkeys after oral administration of [alanine-3-14C]-imidapril. Radio-chromatographic analysis of the metabolites of imidapril from the plasma, urine, and bile of rats, dogs, or monkeys resulted in the detection of at least four metabolites. These four metabolites were isolated and characterized by high performance liquid chromatography (HPLC) and gas chromatography-mass spectrometry(GC-MS). Of these metabolites, M1 (6366 A, CAS 89371-44-8) was pharmacologically active; however, M2, M3, and M4 were inactive. There was no evidence of any glucuronides or sulfates of drug-related compounds, or of the piperazine-dione lactam type metabolites of imidapril or 6366 A in the urine of the animals used. Imidapril was metabolized by hydrolysis at the carboxylic ethyl ester side-chain to give M1, and by cleavage of the amide bond to form M2 and M3. M4 was formed by hydrolysis of M3 and/or cleavage of the amide bond of M1. Qualitatively, the same metabolites were found in all animal species tested; however, quantitatively, there were differences in the amounts of metabolites formed depending on the species.     

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.     

Metabolic disposition of AZD8931, an oral equipotent inhibitor of EGFR,HER2 and HER3 signalling,in rat,dog and man

Abstract

1. This series of studies in rats, dogs and humans (Clinicaltrials.gov identifier: NCT01284595) investigated the pharmacokinetics, tissue distribution, metabolism and excretion of the EGFR, HER2 and HER3 signalling inhibitor AZD8931.

2. Single oral or intravenous doses of 2-(4-[4-(3-chloro-2-fluoro[U-¹⁴C]-phenylamino)-7-methoxy-quinazolin-6-yloxy]-piperidin-1-yl)-N-methyl-acetamide difumarate ([¹⁴C]-AZD8931) were administered.

3. AZD8931 absorption was rapid in all species. Following [¹⁴C]-AZD8931 administration to rats, radioactivity was widely and rapidly distributed, with the highest levels in organs of metabolism and excretion (gastrointestinal tract, liver). Following oral and intravenous [¹⁴C]-AZD8931 administration, excretion of radioactivity by all species occurred predominantly via the bile into faeces, with <5% of the dose being eliminated in urine. In all species, AZD8931 was principally cleared by metabolism. The major route of metabolism was hydroxylation and O-demethylation in rat, and aryl ring oxidation in dog. Metabolism of AZD8931 in humans was attributed to three pathways; oxidation and amine or ether cleavage around the piperidine ring with subsequent glucuronide or sulphate conjugation.

4. AZD8931 is largely cleared by metabolism in the rat, dog and human. Excretory profiles indicate that there are no unique human metabolites.     

The effects of an experimental hepatitis on the metabolic disposition of 3-o-(+)-[14C]methylcatechin in the rat

The induction of an experimental hepatitis did not affect the overall ability of the rat to metabolize the flavanol 3-O-(+)-[14C]methylcatechin by methylation or glucuronidation. The induction of hepatitis did cause a significant increase in metabolite excretion in urine (from 52% of the dose in control rats to 88% in hepatitis). Fecal excretion was correspondingly depressed (44 to 4% of the dose). In bile duct-cannulated rats, the induction of hepatitis prior to 3-O-(+)-[14C]methylcatechin administration resulted in low 14C excretion (38%) in bile (cf. 58% in bile of controls). The data obtained indicate that following induction of hepatitis biliary metabolites reabsorbed from the intestine are not reexcreted in bile in an enterohepatic cycle as in the normal rat but are excreted via the kidney. Induction of hepatitis did not affect the fast clearance of unchanged 3-O-methyl-(+)-catechin from plasma but plasma clearance of the metabolites was reduced from 112 to 89 ml/hr.     

Pharmacokinetics of the selective prostacyclin receptor agonist selexipag in rats,dogs and monkeys

1.?This study examined the pharmacokinetics, distribution, metabolism and excretion of the selective prostacyclin receptor agonist selexipag (NS-304; ACT-293987) and its active metabolite MRE-269 (ACT-33679). The compounds were investigated following oral and/or intravenous administration to intact rats, dogs and monkeys, and bile-duct-cannulated rats and dogs.

2.?After oral administration of [¹⁴C]selexipag, selexipag was well absorbed in rats and dogs with total recoveries of over 90% of the dose, mainly in the faeces. Biliary excretion was the major elimination pathway for [¹⁴C]MRE-269 as well as [¹⁴C]selexipag, while renal elimination was of little importance. [¹⁴C]Selexipag-related radioactivity was secreted into the milk in lactating rats.

3.?Plasma was analysed for total radioactivity, selexipag and MRE-269 in rats and monkeys. Selexipag was negligible in rat plasma due to extensive metabolism, and MRE-269 was present in rat and monkey plasma. A species difference was clearly evident when selexipag was incubated in rat, dog and monkey plasma.

4.?Total radioactivity was rapidly distributed to tissues. The highest concentrations were found in the bile duct and liver without significant accumulation or persistence, while there was limited melanin-associated binding, penetration of the blood–brain barrier and placental transfer of drug-related materials.     

The pharmacokinetics and disposition of MK-0524, a Prosglandin D2 Receptor 1 antagonist, in rats, dogs and monkeys

MK-0524 is a potent, selective and orally active Prosglandin D(2) Receptor 1 (DP(1)) antagonist currently under clinical development for the treatment of niacin-induced flushing. Experiments to study the pharmacokinetics, metabolism and excretion of MK-0524 were conducted in rats, dogs and monkeys. MK-0524 displayed linear kinetics and rapid absorption following an oral dose. Following intravenous (i.v.) administration of MK-0524 to rats and dogs (1 and 5 mg/kg), the mean Cl(p) was approximately 2 and approximately 6 ml/min/kg, the T(1/2) was approximately 7 and approximately 13 h and the Vd(ss) was approximately 1 and approximately 5 L/kg, respectively. In monkeys dosed i.v. at 3 mg/kg, the corresponding values were 8 ml/min/kg, 3 h and 1 L/kg, respectively. Following oral dosing of MK-0524 to rats (5, 25 and 100 mg/kg), dogs (5 mg/kg) and monkeys (3 mg/kg), the absorption was rapid with the mean C(max) occurring between 1 and 4 h. Absolute oral bioavailability values in rats, dogs and monkeys were 50, 70 and 8%, respectively. The major circulating metabolite was the acyl glucuronide of MK-0524 (M2), with ratios of glucuronide to the parent aglycone being highest in the monkey followed by dog and rat. In bile duct-cannulated rats and dogs, MK-0524 was eliminated primarily via acyl glucuronidation followed by biliary excretion of the acyl glucuronide, M2, the major drug-related entity in bile.     

Pharmacokinetics, metabolism and excretion of 14C-monoethyl phthalate (MEP) and 14C-diethyl phthalate (DEP) after single oral and IV administration in the juvenile dog

The pharmacokinetics, metabolism and excretion of monoethyl phthalate (MEP) and diethyl phthalate (DEP) were compared after intravenous or oral administration of [(14)C]MEP or [(14)C]DEP in juvenile beagle dogs. Four male juvenile beagle dogs were treated with a single oral or bolus intravenous dose of either [(14)C]MEP or [(14)C]DEP (164 μg/kg). The absorption, metabolism, excretion and pharmacokinetics of [(14)C]MEP and [(14)C]DEP were nearly identical. [(14)C]DEP was rapidly and nearly completely metabolized to [(14)C]MEP following either intravenous or oral administration. [(14)C]MEP and[(14)C]DEP were rapidly absorbed, the elimination half-life was estimated to be 1 hour. Approximately 90%-96% of the dose was excreted in urine with 2%-3% of the dose in faeces. MEP accounted for the majority of the dose in plasma and urine; in addition, three minor metabolites (M1, M2 and M3) were detected. The minor metabolites were neither phthalic acid nor glucuronide/sulfate conjugates. The nearly identical metabolism and pharmacokinetics of MEP and DEP in juvenile dogs justifies the use of DEP toxicity data in the risk assessment of MEP exposure.