Excretion,distribution and metabolism of 1,2,4-trichlorobenzene in rats

1,2,4-Trichlorobenzene (TCB) labeled with C-14 was given perorally to rats at a dosage of 50 mg/kg for excretion and distribution studies.About 66% and 17% of the oral dose was excreted in the urine and feces, respectively, within 7 days. Trapped radioactivity in the expired air amounted to 2.1% of the dose, but production of labeled carbon dioxide was negligible. Tissue residues were evenly distributed throughout the organs and tissues examined, except for the adipose tissue which consistently had a little higher concentration.The urinary, fecal and expiratory metabolites were identified. Free 2,4,5- and 2,3,5-trichlorophenol (TCP) and their conjugates were mainly detected in the urine. 5- or 6-Sulfhydryl, methylthio, methylsulfoxide and methylsulfone derivatives of TCB were also detected as minor metabolites. Dichlorobenzenes and unchanged TCB were confirmed in the expired air. Reductive dechlroination seems to be catalysed by intestinal microflora enzymes.     

Isolation and identification of metabolites of 2-ethylhexyl diphenyl phosphate in rats

The metabolic fate of 2-ethylhexyl diphenyl phosphate (EHDPP) was studied in male rats. Orally administered ¹⁴C-EHDPP was rapidly absorbed and about 80% of the radioactivity was excreted in the urine and feces in the first 24 h. By 7 days, 48% and 52% of the radioactivity was recovered in urine and feces, respectively. Since biliary excretion was low (6% for 2 days), urine seems to be the major excretion route of EHDPP. Radioactivity was widely distributed in all tissues examined. At 2 h, the concentration was relatively high in blood, liver kidney and adipose tissue. The elimination of radioactivity from adipose tissue and liver was somewhat delayed, but almost all the radioactivity was eliminated by 7 days. The major metabolites in the urine were diphenyl phosphate (DPP) and phenol. p-Hydroxyphenyl phenyl phosphate (OH-DPP) and monophenyl phosphate (MPP) were also identified as minor metabolites.     

Absorption and excretion of suprofen in rats

DL-2-(4-(2-Thienylcarbonyl)phenyl)propionic acid (suprofen, S) was rapidly absorbed in rats after oral administration. Blood levels after a single oral dose of 2, 10, 50, or 100 mg/kg of 3H-S reached maxima within 30 min and were dose-dependent. The major portion of the drug was shown to be absorbed from the upper part of the small intestine and a portion from the stomach. The radioactivity in rat plasma was extensively bound to the plasma protein in vivo; this was found to be unchanged S and four metabolites. Elimination of S and its metabolites from blood was rapid; 3H was mostly excreted in the urine and feces within 24 hr after oral administration of 3H-S. No significant amounts of 14CO2 were excreted in expired air after administration of 14C-S. Rat urine contained S and four metabolites found in rat plasma, accounting for about 60% of the urinary radioactivity. After rats with biliary fistulas were given an oral dose of 2 mg/kg of 3H-S, 41% of the dose was excreted in the bile during 48 hr; there was significant enterohepatic circulation. When single or 21 consecutive daily doses of 3H-S were administered to rats, the blood levels after the multiple doses were higher than those after a single dose but no significant difference was found in excretion of 3H.     

Absorption, metabolism and excretion of [(14)C]mirabegron (YM178), a potent and selective β(3)-adrenoceptor agonist, after oral administration to healthy male volunteers

The mass balance and metabolite profiles of 2-(2-amino-1,3-thiazol-4-yl)-N-[4-(2-{[(2R)-2-hydroxy-2-phenylethyl]amino}ethyl)[U-(14)C]phenyl]acetamide ([(14)C]mirabegron, YM178), a β(3)-adrenoceptor agonist for the treatment of overactive bladder, were characterized in four young, healthy, fasted male subjects after a single oral dose of [(14)C]mirabegron (160 mg, 1.85 MBq) in a solution. [(14)C]Mirabegron was rapidly absorbed with a plasma t(max) for mirabegron and total radioactivity of 1.0 and 2.3 h postdose, respectively. Unchanged mirabegron was the most abundant component of radioactivity, accounting for approximately 22% of circulating radioactivity in plasma. Mean recovery in urine and feces amounted to 55 and 34%, respectively. No radioactivity was detected in expired air. The main component of radioactivity in urine was unchanged mirabegron, which accounted for 45% of the excreted radioactivity. A total of 10 metabolites were found in urine. On the basis of the metabolites found in urine, major primary metabolic reactions of mirabegron were estimated to be amide hydrolysis (M5, M16, and M17), accounting for 48% of the identified metabolites in urine, followed by glucuronidation (M11, M12, M13, and M14) and N-dealkylation or oxidation of the secondary amine (M8, M9, and M15), accounting for 34 and 18% of the identified metabolites, respectively. In feces, the radioactivity was recovered almost entirely as the unchanged form. Eight of the metabolites characterized in urine were also observed in plasma. These findings indicate that mirabegron, administered as a solution, is rapidly absorbed after oral administration, circulates in plasma as the unchanged form and metabolites, and is recovered in urine and feces mainly as the unchanged form.     

The tissue distribution, metabolism, and excretion of octachlorostyrene in the rat

The tissue distribution, metabolism, and elimination of 14C-octachlorostyrene (OCS) were studied in the rat. OCS was absorbed in the gastrointestinal tract after oral administration and distributed in all tissues examined. The highest concentrations were found in fat followed by adrenal glands, skin, and lungs. Decay of radioactivity in the tissues followed first-order kinetics. Approximately 8% of an iv dose was excreted in feces during 7 days after administration, while negligible amounts were found in the urine. More than 90% of the radioactivity in feces was due to the unchanged compound, while pentachlorophenyldichloroacetic acid and heptachlorostyrene in equal proportions accounted for the remaining 10%. A small amount (1%) of the dose was detected in the expired air as carbon dioxide.     

Absorption,distribution, metabolism and excretion of gemigliptin,a novel dipeptidyl peptidase IV inhibitor,in rats

Abstract

1.?The absorption, distribution, metabolism and excretion of a novel dipeptidyl peptidase IV inhibitor, gemigliptin, were examined following single oral administration of ¹⁴C-labeled gemigliptin to rats.

2.?The ¹⁴C-labeled gemigliptin was rapidly absorbed after oral administration, and its bioavailability was 95.2% (by total radioactivity). Distribution to specific tissues other than the digestive organs was not observed. Within 7 days after oral administration, 43.6% of the administered dose was excreted via urine and 41.2% was excreted via feces. Biliary excretion of the radioactivity was about 17.7% for the first 24?h. After oral administration of gemigliptin to rats, the in vivo metabolism of gemigliptin was investigated with bile, urine, feces, plasma and liver samples.

3.?The major metabolic pathway was hydroxylation, and the major circulating metabolites were a dehydrated metabolite (LC15-0516) and hydroxylated metabolites (LC15-0635 and LC15-0636).     

Metabolism and excretion of 3H-digitoxin in the rat

After oral administration of 25 μg/kg ³H-labelled digitoxin (sp. act. 26.2 mCi/mg) to female rats, the total radioactivity in blood and in urine was eliminated with a half-life time of 2 and 1.7 days, respectively. The fecal elimination half-life time had a. biphasic course. The chloroform-soluble and chloroform-insoluble metabolites excreted in urine and feces were determined in order to explain the much shorter half-life time of 0.4 days in feces during the early phase of elimination. In the feces, 45 per cent of the dose excreted within 5 days consisted of chloroform-soluble substances. In this fraction, the main excretion product was digoxigenin-bis-digitoxoside (20 per cent), whereas the percentages of the other glycosides, after the last collection period, amounted to significantly less: 9% digitoxin, 9% digoxin. 5% digitoxigenin-bis-digitoxoside, and 2% digitoxigenin-mono-digitoxoside. The Chromatographic analysis of the chloroform-insoluble fraction, which accounted for 15 per cent of the dose. revealed a conjugation of glucuronic and sulfuric acid with digoxin, and digoxin, 5% digitoxigenin-bis-digitoxosidc. and 2% digitoxigenin-mono-digitoxoside. The contrast, sulfuric acid alone was the main conjugation partner of 3-epi-digitoxigenin. In urine, 4.6 per cent of the administered radioactivity was represented by digoxin, 2 per cent by digitoxin, 1 per cent by digoxigenin-bis-digitoxoside, and 1.4 per cent by polar metabolites. Only traces of digitoxigenin-bis-digitoxoside cind digoxigenin-mono-digitoxoside were detected. The much shorter half-life time of the eliminated radioactivity in feces seems to be due to the higher portion of poorly reabsorbed conjugation products and digoxigeninbis-digitoxoside.     

Chlophentermine-induced abnormalcytoplasmic inclusions in peripheral blood cells of rats and guinea pigs.

The metabolic fate of [¹⁴C]gossypol was studied in the pig following a single oral dose of 6.7 mg/kg (3.7 μCi). Radioactivity was rapidly excreted from the animal body via feces. After 20 days, the total radioactivity recovered in the feces was 94.6% of the administered dose. A total of 2.1% of the radioactivity of administered dose was recovered in the expired CO₂ collected continually for 20 days. This indicates that decarbonilation of gossypol is not a major route of gossypol metabolism in the pig. Radioactivity was least excreted via urine; only 0.7% of the administered dose was recovered in the urine. One day after the administration, the tissues had 32.9% of the administered dose, which was decreased to 1.2% at 20 days. The conceptration of gossypol and its metabolites in the tissues (as indicated by radioactivity) was highest in the muscle, followed by liver, adipose tissues, and the blood. The half-life for the disappearance of radioactivity from the animal body following the administration of [¹⁴C]gossypol was 78 hr. Identification of metabolites was carried out by ultraviolet, infrared, and mass spectrometry in connection with thin-layer autoradiography. Compounds isolated from pig liver were characterized as gossypol, gossypolone, gossypolonic acid, demethylated gossic acid, and presumably apogossypol. Gossypol and metabolites may be conjugated to form glucuronides, sulfates, or hybrids.     

Toxicokinetics of chloroethanol in the rat after single oral administration

The excretion and tissue distribution of ¹⁴C-labelled chloroethanol were studied in rats following single oral administration of 5 and 50 mg/kg body weight.At both dose levels, the radioactivity was rapidly eliminated, mainly in the urine. On the first day after application of 5 mg/kg body weight, 77.2% of the dose were found in the urine, 1.7% in the faeces, and 1.0% as carbon dioxide in the expired air. Only 2.8% were excreted by these routes during the following 3 days. The residual radioactivity remaining in the tissues after 4 days was almost equally distributed and amounted to about 0.4% of the dose in the liver and 3% in the whole organism. At the higher dose level, excretion rates and tissue concentrations were similar.Examination of the urine by anion exchange chromatography on DEAE-Sephadex revealed two metabolites which were identified by GC/MS analysis as thiodiacetic acid and thionyldiacetic acid. These metabolites represented almost the whole urinary radioactivity. They were excreted in approximately equal amounts at the low dose whereas the thiodiacetic acid predominated with about 70% of the urinary radioactivity at the high dose. Unchanged chloroethanol, chloroacetic acid, S-carboxymethylcysteine and sulphonyldiacetic acid were not found in the urine.A preliminary report of this study was presented at the 21st Spring Meeting of the Deutsche Pharmakologische Gesellschaft in Mainz, 1980     

Absorption, metabolism, and excretion of [14C]imidafenacin, a new compound for treatment of overactive bladder, after oral administration to healthy male subjects.

The absorption, metabolism, and excretion of imidafenacin [KRP-197/ONO-8025, 4-(2-methyl-1H-imidazol-1-yl)-2,2-diphenylbutanamide], a new antimuscarinic drug developed for treatment of overactive bladder, were assessed in six healthy male subjects after a single oral administration of 0.25 mg of [(14)C]imidafenacin (approximately 46 microCi). The highest radioactivity in the plasma was observed at 1.5 h after administration. The apparent terminal elimination half-life of the total radioactivity was 72 h. Approximately 65.6 and 29.4% of the administered radioactivity were recovered in the urine and feces, respectively, within 192 h after administration. The metabolite profiling by high-performance liquid chromatography-radiodetector and liquid chromatography/tandem mass spectrometry demonstrated that the main component of radioactivity was unchanged imidafenacin in the 2-h plasma. The N-glucuronide conjugate (M-9) was found as the major metabolite and the oxidized form of the 2-methylimidazole moiety (M-2) and the ring-cleavage form (M-4) were detected as the minor metabolites in the 2-h plasma, but M-4 was found to be the main component in the 12-h plasma. Unchanged imidafenacin, M-9, M-2, and other oxidized metabolites were excreted in the urine, but the unchanged imidafenacin and M-9 were not found in the feces. Two unique metabolites were found in the urine and feces, which were identified as the interchangeable cis- and trans-isomers of 4,5-dihydrodiol forms of the 2-methylimidazole moiety. These findings indicate that imidafenacin is rapidly and well absorbed (at least 65% of dose recovered in urine) after oral administration, circulates in human plasma as the unchanged form, its glucuronide, and other metabolites, and is then excreted in urine and feces as the oxidized metabolites of 2-methylimidazole moiety.     

Characterization of metabolites and disposition of tertiary amyl methyl ether in male F344 rats following inhalation exposure

Tertiary amyl methyl ether (TAME) is a fuel additive used to reduce carbon monoxide in automobile emissions. Because of the potential for human exposure, this study was conducted to develop methods for the characterization and quantitation of metabolites in expired air and excreta of rats exposed to a mixture of [13C]- and [14C]TAME ([2,3,4-13C]- and [2-14C]2-methoxy-2-methylbutane). The distribution of TAME in rats was determined following inhalation exposure, and TAME-derived metabolites were characterized in expired air and urine. Male rats were exposed for 6 h via nose-only inhalation to 2500 ppm [14C/13C]TAME, and expired air, urine and feces were collected for up to 7 days. Over 95% of the total recovered radioactivity was excreted by 48 h after exposure. Recovered radioactivity was expired as organic volatiles (44%) and 14CO2 (3%) and excreted in urine (51%) and feces (1%). Both TAME and its metabolite tertiary amyl alcohol (TAA) accounted for > or =90% of the radiolabel in expired air 0-8 h following exposure termination. Three major urinary metabolites of TAME were identified: (1) a direct glucuronide conjugate of TAA; (2) a product of oxidation at the methylene carbon of TAA (2,3-dihydroxy-2-methylbutane); (3) a glucuronide conjugate of metabolite 2. Metabolite 1 accounted for most of the TAME-derived metabolites excreted 0-8 h following exposure termination. Further metabolic products of TAA (metabolites 2 and 3) accounted for most of the excreted TAME-derived metabolites at later time points.     

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.     

Metabolism and disposition of the flame retardant tris(2,3-dibromopropyl)phosphate in the rat

The metabolism and disposition of the flame retardant, tris(2,3-dibromopropyl)phosphate (Tris-BP), were studied after po and iv administration of the 14C-labeled compound to the male rat. Tris-BP was readily absorbed from the gastrointestinal tract and rapidly distributed throughout the body. The distribution and excretion of Tris-BP derived radioactivity were similar after either po or iv administration. The only effects of route of administration on tissue distribution were slightly higher concentrations in liver after po administration and in lung after iv administration. The initial elimination of Tris-BP derived radioactivity in urine, feces, and as CO2 accounted for approximately 50% of the dose in 24 hr. An analysis of Tris-BP derived radioactivity remaining in the tissues one day after administration indicated that most of the radioactivity in all tissues was in the form of various metabolites rather than the parent compound. The terminal clearance of Tris-BP derived radioactivity from most of the tissues studied was best described by a single component exponential decay with a half-life of approximately 2.5 days. Clearance from liver and kidney was somewhat slower having a half-life of approximately 3.8 days. Approximately 33% of the radioactivity excreted in urine and approximately 50% of the radioactivity excreted in bile were identified by cochromatography with synthesized standards on high performance liquid chromatography (HPLC). Six metabolites and a trace of the parent compound were identified in urine and bile by this method. The six metabolites products of dealkylation and dehydrobromination of the parent compound. The metabolites of Tris-BP isolated from urine and bile were also formed in vitro by NADPH-dependent microsomal enzymes from rat liver. The soluble enzymes from liver metabolized Tris-BP to at least three unidentified polar metabolites.     

Absorption, distribution, metabolism, and excretion of 1,2-dihydro-2,2,4-trimethylquinoline in the male F344 rat

1,2-Dihydro-2,2,4-trimethylquinoline (TMQ), an antioxidant used in the rubber industry, was readily absorbed from the gastrointestinal tract of the male Fischer 344/N rat and rapidly distributed throughout the body tissues. Absorption, distribution, metabolism, and excretion were not significantly affected by dose in the range 11.5-1150 mumol/kg. Following iv administration, the greatest amounts of TMQ-derived radioactivity were present in the high volume tissues including muscle, adipose, skin, liver, and blood. TMQ had no particular affinity for any tissue. TMQ-derived radioactivity was excreted primarily in urine (60-70%) and feces (20-30%) within 3 days after administration. Greater than 99% of the TMQ dose excreted in urine and feces was in the form of metabolites. Urine contained two major and ten minor metabolites while feces contained two major and four minor metabolites. The two major TMQ metabolites in urine were identified by NMR and mass spectroscopy as the O-sulfate conjugate of 1,2-dihydro-6-hydroxy-2,2,4-trimethylquinoline and the monosulfate conjugate of 1,2-dihydro-1,6-dihydroxy-2,2,4-trimethylquinoline. In vitro studies with liver subcellular fractions suggest that most of the metabolites present in urine, feces, and bile are the products of mixed function oxidase activity and conjugates of these metabolites. Multiple exposure of rats to high TMQ doses (1150 mumol/kg) resulted in some bioaccumulation of TMQ-derived radioactivity in all tissues examined, but these residues did not persist when dosing was discontinued.     

Elimination pathways of [14C]losoxantrone in four cancer patients.

Losoxantrone is an anthrapyrazole derivative in Phase III development in the U.S. for solid tumors, notably breast cancer. To obtain information on the routes of elimination of the drug, a study was conducted in four patients with advanced solid tumors, which involved intravenous administration of 100 microCi of [14C]losoxantrone for a total dose of 50 mg/m(2) during the first course of losoxantrone therapy. Blood, urine, and feces were collected for up to 2 weeks and were analyzed for total radioactivity and parent drug. In addition, feces were profiled for the presence of metabolites. Plasma concentrations of total radioactivity exhibited a temporal pattern similar to the parent drug. Combined recovery of administered total radioactivity from urine and feces was 70% with the majority (87%) of this radioactivity excreted in the feces, presumably via biliary excretion. Feces extracts were profiled for metabolites using a high-performance liquid chromatography method developed to separate synthetic standards of previously identified human urinary metabolites. Only intact losoxantrone was found in the feces. About 9% of the dose was excreted in the urine, primarily during the first 24 h and mostly in the form of parent compound. Collectively, these data indicate that fecal excretion of unmetabolized drug via biliary and/or intestinal excretion is the primary pathway of intravenously administered losoxantrone elimination in cancer patients with refractory solid tumors.     

Studies on the metabolism of the neurotoxic tri-o-cresyl phosphate. Distribution, excretion, and metabolism in male cats after a single, dermal application

The metabolism of a single, dermal dose of 50 mg/kg of [14C]tri-o-cresyl phosphate (TOCP) was studied in male cats. TOCP was applied to an unprotected, preclipped area on the back of the neck. Three animals were sacrificed on each of 0.5, 1, 2, 5, and 10 days following application. Radioactivity disappeared biexponentially from the dosing site with a faster initial rate; 73% of the dose disappeared in the first 12 h followed by a slower phase with a half-life of 2.03 days. No radioactivity was detected in the expired air. TOCP was absorbed from the skin and subsequently distributed throughout the body. Generally, the highest concentrations of radioactivity were associated with bile, gall bladder, urinary bladder, kidneys, and liver; the lowest were found in the neural tissues, muscle, and spleen. Within the 10-day experimental period, approximately 28% and 20% of the applied dose were recovered in the urine and feces, respectively. TOCP and its metabolites in the urine, feces, bile, and plasma were analyzed by high performance liquid chromatography and liquid scintillation counting. TOCP was the predominant compound in the feces (26.3% of total fecal radioactivity); it was detected in a smaller percentage in the urine (2.3% of total urinary radioactivity). The major metabolite in the urine was o-cresol followed by di-o-cresyl hydrogen phosphate and o-cresyl dihydrogen phosphate; in the feces di-o-cresyl hydrogen phosphate was the predominant metabolite followed by o-cresyl dihydrogen phosphate. Trace amounts of saligenin cyclic-o-tolyl phosphate, hydroxymethyl, and di(hydroxymethyl) TOCP were also detected in the urine and feces. Other metabolites identified in the urine and feces were the stepwise oxidation products of the methyl group of o-cresol. Unlike the feces, the bile contained mostly metabolites with only trace amounts of TOCP detected at 12 h and 24 h following application. o-Cresyl dihydrogen phosphate and di-o-cresyl hydrogen phosphate were the prevalent metabolites in the bile and plasma. While di(hydroxymethyl) TOCP was present in trace amounts in plasma, an appreciable amount of saligenin cyclic-o-tolyl phosphate, believed to be the active neurotoxic metabolite, was detected. This study shows that skin is an important port of entry for TOCP. Since TOCP represents organophosphorous chemicals capable of producing delayed neurotoxicity in test animals and in humans, it is essential that industrial hygiene control prevents skin contamination of workers handling these chemicals.     

Excretion and biotransformation of alfentanil and sufentanil in rats and dogs

The excretion and biotransformation of alfentanil (ALF) and sufentanil (SUF), two recent analogues of the synthetic opioid fentanyl, were studied after single iv administration of the tritium-labeled drugs in male rats and dogs. The drugs were almost completely metabolized in the two species, which resulted in a large number of metabolites. The excretion of the metabolites was rapid and exceeded 95% within 4 days, except for that of ALF metabolites in dogs (about 85%). For ALF, excretion of the radioactivity with the urine (73% in rats, about 76% in dogs) exceeded that with the feces. For SUF, excretion of the radioactivity with the urine amounted to 38 and 60% and that with the feces to 62 and 40%, in rats and dogs, respectively. Bile-cannulated rats excreted 68% with the bile within 24 hr after SUF dosing, and about 22% of this biliary radioactivity was subjected to enterohepatic circulation. After an ALF dose, the biliary excretion amounted to 24%, and the enterohepatic circulation was minimal. The main metabolic pathways of the two drugs were the oxidative N-dealkylation at the piperidine nitrogen and at the amide nitrogen, oxidative O-demethylation, aromatic hydroxylation, and the formation of ether glucuronides. N-[4-(Hydroxymethyl)-4-piperidinyl]-N-phenylpropanamide (M6) was the main metabolite of both ALF and SUF in rats. In dogs, the glucuronide of N-(4-hydroxyphenyl)propanamide (M5) was the main metabolite of ALF. After SUF dosing in dogs, N-[4-(methoxymethyl)-4-piperidinyl]-N-phenylpropanamide was more abundant than M5.     

Studies on the toxicology of hexachlorobenzene

Female rats were dosed intraperitoneally with ¹⁴C-hexachlorobenzene. The drug was administered on 2 or 3 occasions. The total doses amounted to 260 and 390 mg/kg ¹⁴C-hexachlorobenzene, respectively. Urine and feces from the animals were collected over a period of 4 weeks after the first injection. Both excreta and some tissues of the animals were examined for their content of radioactivity and for hexachlorobenzene and its metabolites. Gas chromatography, isotope dilution analysis, and combined gas chromatography-mass spectrometry were used to identify the metabolites of hexachlorobenzene. In urine pentachlorophenol, tetrachlorohydroquinone, and pentachlorothiophenol were present as major metabolites. One of the isomers of tetrachlorothiophenol was present as a minor metabolite. In the feces pentachlorophenol and penta-chlorothiophenol only were identified.At the end of the experiment, carbon-14 excreted with urine and feces amounted to 7% and 27%, respectively, of the radioactivity administered.More than 90% of carbon-14 excreted in urine was contained in the major metabolites. In the feces about 30% of the excreted radioactivity was bound to metabolites and about 70% was contained in the unchanged drug, while in the tissues of the animals only pentachlorophenol was detected in measurable amounts, accounting for 10% of label in blood and less than 0.1% of carbon-14 determined in body fat. Total radioactivity contained in the metabolites detected in the animal body and in the excreta at the end of the experiment accounted for about 16% of the administered radioactivity.The authors thank Miss A. Springer and Mr. K. Wittkamp for their technical assistance.     

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.     

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)