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.     

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.     

Biliary excretion and enterohepatic circulation of 1-nitropyrene metabolites in Fischer-344 rats

1-Nitropyrene (1-NP), present in diesel engine emissions, is a potent mutagen to bacteria, such as those found in mammalian intestinal tract, which contain nitroreductase enzymes. The purposes of this study were to determine the importance of bile as a route of excretion of 1-NP metabolites and to determine if reabsorption of biliary metabolites required the presence of intestinal bacteria. The bile ducts of male Fischer-344 rats were cannulated, 0.3 or 1.2 mumoles [3H]1-NP was given i.v., and bile, urine, and feces were collected for 24 hr. Biliary excretion accounted for 70 (80%) or 170 (60%) nmoles of [3H]1-NP after the low and high dose, respectively, with half-times for excretion of 1.7 hr +/- 0.3 (+/- S.E.M.) and 3.4 hr +/- 1.6 (+/- S.E.M.). Excretion of [3H]1-NP equivalents in the urine was linearly related to dose, with 6 or 16 nmoles (8%) excreted in 24 hr. At the low dose, more radioactivity appeared in the urine in control rats compared to bile-duct cannulated rats, suggesting that reabsorption of 1-NP metabolites occurred. Pretreatment of rats with orally administered antibiotics prior to i.v. injection of 0.3 mumole [3H]1-NP decreased radioactivity excreted in urine compared to untreated controls, suggesting that intestinal microorganisms may alter the biliary metabolites of 1-NP to facilitate reabsorption. Pretreatment of rats with buthionine sulfoximine, a glutathione depletor, decreased the excretion of certain biliary metabolites, suggesting that they were mercapturic acids of 1-NP metabolites. In summary, the results of these studies indicate that bile was an important route of excretion of nitropyrene metabolites. A portion of the excreted metabolites was reabsorbed from the gut, and this reabsorption required the presence of gut microorganisms.     

Fate of silvex following oral administration to humans

The fate of silvex [2-(2,4,5-trichlorophenoxy)propionic acid] was defined in seven men and in one woman following oral administration of 1 mg/kg. No adverse effects were observed. Samples of blood plasma, urine, and feces were collected at designated time intervals through 168 hr. Plasma samples were analyzed for silvex only, while samples of urine and feces were analyzed for silvex, silvex conjugate(s), 2,4,5-trichlorophenol, and 2,4,5-trichlorophenol conjugate(s). Apparent first-order kinetics described the biphasic clearance of silvex from plasma and excretion in urine. The half-life values for clearance of silvex from plasma were 4.0 +/- 1.9 and 16.5 +/- 7.3 hr for the initial and terminal phases, respectively. Peak plasma levels of silvex occurred within 2-4 hr after dosage. Within 24 hr after administration, 65% of the administered dose had been excreted in urine. Silvex was excreted in urine as silvex and silvex conjugate(s). The half-life values for excretion of silvex per se in urine were 5.0 +/- 1.8 and 25.9 +/- 6.3 hr for the two phases, respectively. Small amounts (3.2% or less) of silvex and/or silvex conjugate(s) were eliminated in feces. Recovery of silvex and its conjugate(s) in urine and feces through 168 hr ranged from 66.6 to 95.1% of the administered dose, with a mean value and standard deviation of 80.3 +/- 10.5%. In humans, silvex is readily absorbed after ingestion and subsequently readily excreted, predominantly via the urine.     

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.     

Excretion of 14C-labeled cyanide in rats exposed to chronic intake of potassium cyanide

The excretion of an acute dose of 14C-labeled cyanide in urine, feces, and expired air was studied in rats exposed to daily intake of unlabeled KCN in the diet for 6 weeks. Urinary excretion was the main route of elimination of cyanide carbon in these rats, accounting for 83% of the total excreted radioactivity in 12 hr and 89% of the total excreted radioactivity in 24 hr. The major excretion metabolite of cyanide in urine was thiocyanate, and this metabolite accounted for 71 and 79% of the total urinary activity in 12 hr and 24 hr, respectively. The mean total activity excreted in expired air after 12 hr was only 4%, and this value did not change after 24 hr. Of the total activity in expired air in 24 hr, 90% was present as carbon dioxide and 9% as cyanide. When these results were compared with those observed for control rats, it was clear that the mode of elimination of cyanide carbon in both urine and breath was not altered by the chronic intake of cyanide.     

Pharmacokinetics, metabolism, and excretion of irinotecan (CPT-11) following I.V. infusion of [(14)C]CPT-11 in cancer patients.

This study determined the disposition of irinotecan hydrochloride trihydrate (CPT-11) after i.v. infusion of 125 mg/m(2) (100 microCi) [(14)C]CPT-11 in eight patients with solid tumors. Mean +/- S.D. recovery of radioactivity in urine and feces was 95.8 +/- 2.7% (range 92.2-100.3%, n = 7) of dose. Radioactivity in blood, plasma, urine, and feces was determined for at least 168 h after dosing. Fecal excretion accounted for 63.7 +/- 6.8 (range 54.2-74.9%, n = 7) of dose, whereas urinary excretion accounted for 32.1 +/- 6.9% (range 21.7-43.8%; n = 7) of dose. One patient with a biliary T-tube excreted 30.1% of dose in bile, 14.2% in feces, and 48.2% in urine. Quantitative radiometric HPLC revealed that CPT-11 was the major excretion product in urine, bile, and feces. Aminopentane carboxylic acid (APC) and SN-38 glucuronide (SN-38G) were the most significant metabolites in urine and bile, whereas SN-38 and NPC, a primary amine metabolite, were relatively minor excretion products. SN-38 and APC were the most significant metabolites in feces. The relatively higher amount of SN-38 in feces compared with bile is presumably due to hydrolysis of SN-38G to SN-38 by enteric bacterial beta-glucuronidases. There was close correspondence between quantitative fluorescence HPLC and mass balance findings. CPT-11 was the major circulating component in plasma (55% of the mean radiochemical area under the curve), and CPT-11, SN-38, SN-38G, and APC accounted for 93% of the mean radiochemical AUC. These results show that the parent drug and its three major metabolites account for virtually all CPT-11 disposition, with fecal excretion representing the major elimination pathway.     

Disposition of [14C]methyl bromide in rats after inhalation

Methyl bromide is used as a disinfectant to fumigate soil and a wide range of stored food commodities in warehouses and mills. Human exposure occurs during the manufacture and use of the chemical. The purpose of this investigation was to determine the disposition and metabolism of [14C]methyl bromide in rats after inhalation. Male Fischer-344 rats were exposed nose only to a vapor concentration of 337 nmol [14C]methyl bromide/liter air (9.0 ppm, 25 degrees C, 620 torr) for 6 hr. Urine, feces, expired air, and tissues were collected for up to 65 hr after exposure. Elimination of 14C as 14CO2 was the major route of excretion with about 47% (3900 nmol/rat) of the total [14C]methyl bromide absorbed excreted by this route. CO2 excretion exhibited a biphasic elimination pattern with 85% of the 14CO2 being excreted with a half-time of 3.9 +/- 0.1 hr (means +/- SE) and 15% excreted with a half-time of 11.4 +/- 0.2 hr. Half-times for elimination of 14C in urine and feces were 9.6 +/- 0.1 and 16.1 +/- 0.1 hr, respectively. By 65 hr after exposure, about 75% of the initial radioactivity had been excreted with 25% remaining in the body. Radioactivity was widely distributed in tissues immediately following exposure with lung (250 nmol equivalents/g), adrenal (240 nmol equivalents/g), kidney (180 nmol equivalents/g), liver (130 nmol equivalents/g), and nasal turbinates (110 nmol equivalents/g) containing the highest concentrations of 14C. Radioactivity in livers immediately after exposure accounted for about 17% of the absorbed methyl bromide. Radioactivity in all other tissues examined accounted for about 10% of the absorbed methyl bromide. Elimination half-times of 14C from tissues were on the order of 1.5 to 8 hr. In all tissues examined, over 90% of the 14C in the tissues was methyl bromide metabolites. The data from this study indicate that after inhalation methyl bromide is rapidly metabolized in tissues and readily excreted.     

The disposition and metabolism of a hypnotic benzodiazepine, quazepam, in the hamster and mouse

The disposition of 14C-quazepam (7-chloro-(2,2,2-trifluoroethyl) [5-14C]-5-o-fluorophenyl-1,3-dihydro-2H-1,4-benzodiazepin-2-thione), a new benzodiazepine hypnotic, was studied in hamsters and mice after iv and po dosing. In both species, quazepam was rapidly absorbed, as indicated by the plasma Cmax being reached within 1 hr of an oral dose (5 mg/kg). Also, radioactivity is essentially completely absorbed in both species, since the percentage of dose excreted in the urine was not dependent on the route of drug administration. Radioactivity was widely distributed in the tissues of both species; however, it was concentrated (relative to plasma) only in the liver and kidneys. In hamsters, 66-77% of the radioactivity was excreted within 48 hr, and 97% within 7 days of dosing (57% found in urine and 40% in feces after iv; 54% in urine and 43% in feces after po dosing). In mice, 86-88% of the radioactivity was excreted within 24 hr, and 98% within 4 days of dosing (43% in urine and 56% in feces after iv, 37% in urine and 61% in feces after po dosing). In both species, plasma levels of quazepam, measured by GLC, accounted for a very small percentage of plasma radioactivity and the elimination half-life was short (2.4 hr in hamster and 1.2 hr in mice), indicating extensive first pass metabolism for this drug. TLC analysis of plasma and urine extracts from both species showed biotransformation of quazepam involved substitution of oxygen for sulfur, followed by: (a) N-dealkylation, 3-hydroxylation, and conjugation or (b) 3-hydroxylation and conjugation.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Metabolism and disposition of the dopaminergic agonist 5-hydroxy-6-methyl-2-di-n-propylaminotetralin in the rat

As part of a program to investigate the metabolism and disposition of putative dopamine receptor agonists, DK-118 (5-hydroxy-6-methyl-2-di-n-propylaminotetralin) was chosen for study in the rat. Following a 3.85 mg/kg (ip) dose of 5-hydroxy[6-14C]methyl-2-di-n-propylaminotetralin, an average (+/- SD) of 100.3 +/- 12.2% was recovered in 67 hr: 77.2 +/- 7.9% in urine and 23.1 +/- 6.2% in feces. No excretion of 14CO2 was observed. In bile duct-cannulated animals, an average of 31.6% of the dose was recovered in the bile within 6 hr. After injection of bile containing radiolabeled drug/metabolites into the lumen of the duodenum, 30.2 +/- 1.7% of the injected radioactivity was recovered in the urine, suggesting enterohepatic circulation of some of the drug/metabolites excreted in bile. Highest concentrations of tissue radioactivity, 0.5 hr after ip injection of 14C-DK-118, were found in lung, kidney, and liver. Only a small amount of unchanged DK-118 is excreted into urine and bile; HPLC radiochromatography separated five metabolites in urine and at least eight metabolites in bile. The three major metabolites in urine (70% of urinary radioactivity) have been identified as 5-hydroxy-6-carboxy-2-di-n-propylaminotetralin, 5-hydroxy-6-carboxy-2-n-propylaminotetralin, and 5-hydroxy-6-methyl-2-n-propylaminotetralin-O-sulfate. The two major biliary metabolites have been identified as 5-hydroxy-6-carboxy-2-n-propylaminotetralin and an acid-labile conjugate of DK-118. Together, these data indicate that DK-118 is metabolized in the rat by a combination of N-dealkylation, oxidation of the 6-methyl carbon, and conjugation with sulfate.     

Mass balance study of [1?C]eribulin in patients with advanced solid tumors

This mass balance study investigated the metabolism and excretion of eribulin, a nontaxane microtubule dynamics inhibitor with a novel mechanism of action, in patients with advanced solid tumors. A single approximately 2 mg (approximately 80 μCi) dose of [1?C]eribulin acetate was administered as a 2 to 5 min bolus injection to six patients on day 1. Blood, urine, and fecal samples were collected at specified time points on days 1 to 8 or until sample radioactivity was ≤1% of the administered dose. Mean plasma eribulin exposure (627 ng · h/ml) was comparable with that of total radioactivity (568 ng Eq · h/ml). Time-matched concentration ratios of eribulin to total radioactivity approached unity in blood and plasma, indicating that unchanged parent compound constituted almost all of the eribulin-derived radioactivity. Only minor metabolites were detected in plasma samples up to 60 min postdose, pooled across patients, each metabolite representing ≤0.6% of eribulin. Elimination half-lives for eribulin (45.6 h) and total radioactivity (42.3 h) were comparable. Eribulin-derived radioactivity excreted in feces was 81.5%, and that of unchanged eribulin was 61.9%. Renal clearance (0.301 l/h) was a minor component of total eribulin clearance (3.93 l/h). Eribulin-derived radioactivity excreted in urine (8.9%) was comparable with that of unchanged eribulin (8.1%), indicating minimal excretion of metabolite(s) in urine. Total recovery of the radioactive dose was 90.4% in urine and feces. Overall, no major metabolites of eribulin were detected in plasma. Eribulin is eliminated primarily unchanged in feces, whereas urine constitutes a minor route of elimination.     

Disposition and biotransformation of the acetylenic retinoid tazarotene in humans

Oral tazarotene, an acetylenic retinoid, is in clinical development for the treatment of psoriasis. The disposition and biotransformation of tazarotene were investigated in six healthy male volunteers, following a single oral administration of a 6 mg (100 microCi) dose of [14C]tazarotene, in a gelatin capsule. Blood levels of radioactivity peaked 2 h postdose and then rapidly declined. Total recovery of radioactivity was 89.2+/-8.0% of the administered dose, with 26.1+/-4.2% in urine and 63.0+/-7.0% in feces, within 7 days of dosing. Only tazarotenic acid, the principle active metabolite formed via esterase hydrolysis of tazarotene, was detected in blood. One major urinary oxidative metabolite, tazarotenic acid sulfoxide, accounted for 19.2+/-3.0% of the dose. The majority of radioactivity recovered in the feces was attributed to tazarotenic acid representing 46.9+/-9.9% of the dose and only 5.82+/-3.84% of dose was excreted as unchanged tazarotene. Thus following oral administration, tazarotene was rapidly absorbed and underwent extensive hydrolysis to tazarotenic acid, the major circulating species in the blood that was then excreted unchanged in feces. A smaller fraction of tazarotenic acid was further metabolized to an inactive sulfoxide that was excreted in the urine.     

Metabolism and excretion of [(14)C]celecoxib in healthy male volunteers.

We determined the disposition of a single 300-mg dose of [(14)C]celecoxib in eight healthy male subjects. The [(14)C]celecoxib was administered as a fine suspension reconstituted in 80 ml of an apple juice/Tween 80/ethanol mixture. Blood and saliva samples were collected at selected time intervals after dosing. All urine and feces were collected on the 10 consecutive days after dose administration. Radioactivity in each sample was determined by liquid scintillation counting or complete oxidation and liquid scintillation counting. Metabolic profiles in plasma, urine, and feces were obtained by HPLC, and metabolites were identified by mass spectrometry and NMR. [(14)C]Celecoxib was well absorbed, reaching peak plasma concentrations within 2 h of dosing. [(14)C]Celecoxib was extensively metabolized, with only 2.56% of the radioactive dose excreted as celecoxib in either urine or feces. The total percentage of administered radioactive dose recovered was 84.8 +/- 4.9%, with 27.1 +/- 2.2% in the urine and 57.6 +/- 7.3% in the feces. The oxidative metabolism of celecoxib involved hydroxylation of celecoxib at the methyl moiety followed by further oxidation of the hydroxyl group to form a carboxylic acid metabolite. The carboxylic acid metabolite of celecoxib was conjugated with glucuronide to form the 1-O-glucuronide. The percentages of the dose excreted in the feces as celecoxib and the carboxylic acid metabolite were 2.56 +/- 1.09 and 54.4 +/- 6.8%, respectively. The majority of the dose excreted in the urine was the carboxylic acid metabolite (18.8 +/- 2.1%); only a small amount was excreted as the acyl glucuronide (1.48 +/- 0.15%).     

Metabolism and excretion of the dipeptidyl peptidase 4 inhibitor [14C]sitagliptin in humans.

The metabolism and excretion of [(14)C]sitagliptin, an orally active, potent and selective dipeptidyl peptidase 4 inhibitor, were investigated in humans after a single oral dose of 83 mg/193 muCi. Urine, feces, and plasma were collected at regular intervals for up to 7 days. The primary route of excretion of radioactivity was via the kidneys, with a mean value of 87% of the administered dose recovered in urine. Mean fecal excretion was 13% of the administered dose. Parent drug was the major radioactive component in plasma, urine, and feces, with only 16% of the dose excreted as metabolites (13% in urine and 3% in feces), indicating that sitagliptin was eliminated primarily by renal excretion. Approximately 74% of plasma AUC of total radioactivity was accounted for by parent drug. Six metabolites were detected at trace levels, each representing <1 to 7% of the radioactivity in plasma. These metabolites were the N-sulfate and N-carbamoyl glucuronic acid conjugates of parent drug, a mixture of hydroxylated derivatives, an ether glucuronide of a hydroxylated metabolite, and two metabolites formed by oxidative desaturation of the piperazine ring followed by cyclization. These metabolites were detected also in urine, at low levels. Metabolite profiles in feces were similar to those in urine and plasma, except that the glucuronides were not detected in feces. CYP3A4 was the major cytochrome P450 isozyme responsible for the limited oxidative metabolism of sitagliptin, with some minor contribution from CYP2C8.     

Comparative disposition and metabolism of 1,2,3-trichloropropane in rats and mice.

1,2,3-Trichloropropane (TCP) has been used as a solvent and degreasing agent and as an intermediate in pesticide manufacture. TCP is currently the subject of a National Toxicology Program chronic toxicity study. The present study is part of a larger effort to characterize the toxicity of TCP. Following acute oral exposure of male and female F344 rats (30 mg/kg) and male B6C3F1 mice (30 and 60 mg/kg), TCP was rapidly absorbed, metabolized, and excreted. The major route of excretion of TCP was in the urine. By 60 hr postdosing, rats had excreted 50% and mice 65% of the administered dose by this route. Exhalation as 14CO2 and excretion in the feces each accounted for 20% of the total dose in 60 hr rats and 20 and 15%, respectively, in mice. No apparent sex-related differences were observed in the ability of the rats to excrete TCP-derived radioactivity. At 60 hr, TCP-derived radioactivity was most concentrated in the liver, kidney, and forestomach in both rats and male mice. Male mice eliminated TCP-derived radioactivity more rapidly than rats and lower concentrations of radioactivity were found in tissues 60 hr after dosing in mice. Two urinary metabolites were isolated and identified by NMR, mass spectroscopy, and comparison with synthetic standards, as N-acetyl- and S-(3-chloro-2-hydroxypropyl)cysteine. Analyses of the early urine (0-6 hr) showed this mercapturic acid to be the major metabolite in rat urine and was only a minor component in mouse urine. 2-(S-Glutathionyl)malonic acid was identified by NMR and mass spectrometry and by chemical synthesis as the major biliary metabolite in rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Absorption,metabolism and excretion of [14C]gemigliptin,a novel dipeptidyl peptidase 4 inhibitor,in humans

Abstract

1. Gemigliptin (formerly known as LC15-0444) is a newly developed dipeptidyl peptidase 4 inhibitor for the treatment of type 2 diabetes. Following oral administration of 50?mg (5.4?MBq) [¹⁴C]gemigliptin to healthy male subjects, absorption, metabolism and excretion were investigated.

2. A total of 90.5% of administered dose was recovered over 192?hr postdose, with 63.4% from urine and 27.1% from feces. Based on urinary recovery of radioactivity, a minimum 63.4% absorption from gastrointestinal tract could be confirmed.

3. Twenty-three metabolites were identified in plasma, urine and feces. In plasma, gemigliptin was the most abundant component accounting for 67.2%?～?100% of plasma radioactivity. LC15-0636, a hydroxylated metabolite of gemigliptin, was the only human metabolite with systemic exposure more than 10% of total drug-related exposure. Unchanged gemigliptin accounted for 44.8%?～?67.2% of urinary radioactivity and 27.7%?～?51.8% of fecal radioactivity. The elimination of gemigliptin was balanced between metabolism and excretion through urine and feces. CYP3A4 was identified as the dominant CYP isozyme converting gemigliptin to LC15-0636 in recombinant CYP/FMO enzymes.     

Metabolism of proxyphylline in man. Isolation and identification of metabolites in urine

The urinary excretion of radioactivity has been measured in man following intravenous injection of 400 mg of [8-14C]proxyphylline. Of the radioactive dose, 95% was recovered in urine 3 days after drug administration. Proxyphylline metabolites were isolated from the urine excreted between 8 and 19.5 hr after drug administration and separated into four different fractions. Unmetabolized proxyphylline accounted for 22% of the excreted radioactivity. The main metabolite was identified as 1-methyl-7-(beta-hydroxypropyl)xanthine, which accounted for 60--65% of the excreted radioactivity. About 1% was excreted as the corresponding 1-methyl-7-(beta-hydroxypropyl)uric acid. Nine percent of the dose was excreted as glucuronic acid conjugates, mainly as proxyphylline glucuronide, but 0.5--1% of 1-methyl-7-(beta-hydroxypropyl)xanthine glucuronide, was also found. The previously postulated metabolite, theophylline, was not excreted in detectable amounts.     

Biotransformation and mass balance of tipranavir, a nonpeptidic protease inhibitor, when co-administered with ritonavir in Sprague-Dawley rats

In this study, tipranavir (TPV) biotransformation and disposition when co-administered with ritonavir (RTV) were characterized in Sprague-Dawley rats. Rats were administered a single intravenous (5 mg kg(-1)) or oral (10 mg kg(-1)) dose of [(14)C]TPV with co-administration of RTV (10 mg kg(-1)). Blood, urine, faeces and bile samples were collected at specified time-points over a period of 168 h. Absorption of TPV-related radioactivity ranged from 53.2-59.6%. Faecal excretion was on average 86.7% and 82.4% (intravenous) and 75.0% and 82.0% (oral) of dosed radioactivity in males and females, respectively. Urinary excretion was on average 4.06% and 6.73% (intravenous) and 9.71% and 8.28% (oral) of dosed radioactivity in males and females, respectively. In bile-duct-cannulated rats, 39.8% of the dose was recovered in bile. After oral administration, unchanged TPV accounted for the majority of the radioactivity in plasma (85.7-96.3%), faeces (71.8-80.1%) and urine (33.3-62.3%). The most abundant metabolite in faeces was an oxidation metabolite R-2 (5.9-7.4% of faecal radioactivity, 4.4-6.1% of dose). In urine, no single metabolite was found to be significant, and comprised <1% of dose. TPV when co-administered with RTV to rats was mainly excreted in feces via bile and the parent compound was the major component in plasma and faeces.     

Pharmacokinetics of N-(4-hydroxyphenyl)-all-trans-retinamide in rats

The concentration of N-(4-hydroxyphenyl)-all-trans-retinamide (HPR) was determined in plasma and a variety of tissues from rats after an intravenous dose (5 mg/kg). The plasma concentration-time curve could be accurately described by a triexponential equation. The apparent volume of distribution of HPR was approximately 10-12 liter/kg and the terminal half-life was 12 hr. Metabolites of HPR were more abundant than intact drug in most tissues 24 hr after the iv dose. A 5-day excretion study with radiolabeled HPR revealed that less than 2% of a single iv dose (5 mg/kg) is excreted as unmetabolized HPR in urine and feces and that most of the radioactivity is eliminated in the feces. HPR was incompletely absorbed after an oral dose (10 mg/kg).