Disposition of a low dose of bisphenol a in male and female cynomolgus monkeys.

Bisphenol A (BPA) is a weak estrogenic compound mass-produced with potential human exposure. Following a single oral or intravenous (iv) dose of 100 microg/kg [ring-14C(U)] radiolabeled bisphenol A (14C-BPA) to male and female cynomolgus monkeys, 79-86% of the administered radioactivity was excreted in urine over 7 days, and most of the urinary excretion was recovered by 24 h after dosing, a large part of this occurring within 12 h. The fecal excretion of radioactivity over 7 days was minimal (1.8-3.1%). Toxicokinetic parameters obtained from plasma 14C-BPA-derived radioactivity during 48 h were C(max) = 104-107 ng-eq/ml between 0.25 and 2 h, and AUC(oral) = 244-265 ng-eq*h/ml after oral dosing. In the case of the iv dose, AUC(iv) was 377-382 ng-eq*h/ml, and the bioavailability was 0.66-0.70. The terminal elimination half-life was larger post-iv dose (t(1/2iv) = 13.5-14.7 h) than post-oral dose (t(1/2oral) = 9.63-9.80 h). After iv dose, the fast-phase half-life (t(1/2f)) of total radioactivity was 0.61-0.67 h. The t(1/2f) of unchanged 14C-BPA for females (0.39 h) was smaller than that for males (0.57 h). These results suggested the distribution of lipophilic 14C-BPA in adipose tissue after iv dose, in contrast to first pass metabolism after oral dose. 14C-BPA-derived radioactivity was strongly bound to plasma protein (f(p) = 0.055). Radio-HPLC analysis suggested the predominant plasma and urinary metabolites were mono- and diglucuronide of 14C-BPA and unchanged 14C-BPA was very low (< or =1.5%) after oral dose. These results indicate that the intestinal absorption and metabolism of BPA was rapid and extensive, and the major metabolites, glucuronide conjugates of 14C-BPA, were rapidly excreted into urine in monkeys.     

The effects of dose, route, and repeated dosing on the disposition and kinetics of tetrabromobisphenol A in male F-344 rats.

Studies were conducted to characterize the metabolic and dispositional fate of (14)C-tetrabromobisphenol A (TBBPA)-a commonly used brominated flame retardant, in male Fischer-344 rats. The percent of dose eliminated as total radioactivity in feces at 72 h following three different single oral doses (2, 20, or 200 mg/kg) of (14)C-TBBPA was 90% or greater for all doses. Most of the dose was eliminated in the first 24 h. At 72 h after administration of the highest dose, the amounts of (14)C found in the tissues were minimal (0.2-0.9%). With repeated daily oral doses (20 mg/kg) for 5 or 10 days, the cumulative percent dose eliminated in the feces was 85.1+/-2.8 and 97.9+/-1.1, respectively. In all studies radioactivity recovered in urine was minimal, <2%. Repeated dosing did not lead to retention in tissues. Following iv administration, feces was also the major route of elimination. Following iv administration of TBBPA, the radiolabel found in the blood decreased rapidly and could be described by a biexponential equation, consistent with a two-compartment model. The key calculated kinetic parameters are terminal elimination half-life (t(1/2)beta)=82 min; area under the blood concentration-time curve from time 0 to infinity (AUC)=1440 mug x min/ml; and apparent clearance (CL)=2.44 ml/min. Although readily absorbed from the gut, systemic bioavailability of TBBPA is low (<2%). It is extensively extracted and metabolized by the liver and the metabolites (glucuronides) exported into the bile. About 50% of an oral dose (20 mg/kg) was found in the bile within 2 h. This extensive extraction and metabolism by the liver greatly limits exposure of internal tissues to TBBPA following oral exposures.     

Distribution, excretion, and metabolism of butylbenzyl phthalate in the rat

The disposition of butylbenzyl phthalate (BBP), a widely used plasticizer, was evaluated after oral and iv administration to rats. Male Fischer-344 rats were dosed with [14C]BBP at 2, 20, 200, or 2000 mg/kg po or 20 mg/kg iv to determine the effects of dose on rates and routes of excretion. In 24 h, 61-74% of the dose was excreted in the urine and 13-19% in the feces at 2-200 mg/kg. At the 2000-mg/kg dose, 16% of the 14C was excreted in the urine and 57% in the feces. Urinary 14C was composed of monophthalate derivatives (MP: 10-42% of the dose) and glucuronides of these monophthalate derivatives (2-21% of the dose). At 4 h after iv administration of BBP (20 mg/kg), 53-58% of the dose was excreted in the bile of anesthetized rats. No parent compound was found in the bile, but monobutyl phthalate-glucuronide and monobenzyl phthalate-glucuronide (26% and 13% of the dose, respectively) and trace amounts of free monoesters (2% of the dose) and unidentified metabolites (14% of the dose) were present. Although BBP is an asymmetric diester with the potential of forming equal amounts of monobutyl phthalate (MBuP) and monobenzyl phthalate (MBeP), larger quantities of MBuP were formed (MBuP = 44% versus MBeP = 16% of the dose). The half-lives of BBP, MP, and total 14C in blood (20 mg/kg, iv) were 10 min, 5.9 h, and 6.3 h, respectively. This study indicates that BBP is rapidly metabolized and that the major route of excretion of metabolites is biliary. These metabolites are reabsorbed and ultimately eliminated in the urine.     

Absorption, distribution and excretion of the new thienopyridine agent prasugrel in rats

Prasugrel is converted to the pharmacologically active metabolite after oral dosing in vivo. In this study, (14)C-prasugrel or prasugrel was administered to rats at a dose of 5 mg kg(-1). After oral and intravenous dosing, the values of AUC(0-infinity) of total radioactivity were 36.2 and 47.1 microg eqx h ml(-1), respectively. Oral dosing of unlabeled prasugrel showed the second highest AUC(0-8) of the active metabolite of six metabolites analyzed. Quantitative whole body autoradiography showed high radioactivity concentrations in tissues for absorption and excretion at 1 h after oral administration, and were low at 72 h. The excretion of radioactivity in the urine and feces were 20.2% and 78.7%, respectively, after oral dosing. Most radioactivity after oral dosing was excreted in bile (90.1%), which was reabsorbed moderately (62.4%). The results showed that orally administered prasugrel was rapidly and fully absorbed and efficiently converted to the active metabolite with no marked distribution in a particular tissue.     

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.     

Disposition of low doses of 14C-bisphenol A in male, female, pregnant, fetal, and neonatal rats

Bisphenol A (BPA) is a weak xenestrogen (ADI=50 g kg^–1, US EPA) which is mass-produced, with potential for human exposure. To study absorption, distribution, excretion, and metabolism of BPA, BPA labeled with carbon-14 was administered p.o. to male and female Fischer (F344) rats at relatively low doses (20, 100, and 500 g kg^–1), and i.v. injected at 100 and 500 g kg^–1. ¹⁴C-BPA (500 g kg^–1) was also administered orally to pregnant and lactating rats to examine the transfer of radioactivity to fetuses, neonatal rats, and milk. Radioluminographic determination using phosphor imaging plates was employed to achieve highly sensitive determination of radioactivity. Absorption ratios of radioactivity after three oral doses were high (35–82%); parent ¹⁴C-BPA in the circulating blood was quite low, however, suggesting considerable first-pass effect. After an oral dose of 100 g kg^{–1 14}C-BPA, the radioactivity was distributed and eliminated rapidly, but remained in the intestinal contents, liver, and kidney for 72 h. The major metabolite in the plasma and urine was BPA glucuronide, whereas most of the BPA was excreted with the feces as free BPA. A second peak in the time-course of plasma radioactivity suggested enterohepatic recirculation of BPA glucuronide. There was limited distribution of ¹⁴C-BPA to the fetus and neonate after oral administration to the dam. Significant radioactivity was not detected in fetuses on gestation days 12 and 15. On day 18, however, radioactivity was detected in the fetal intestine and urinary bladder 24 h after oral dosing of ¹⁴C-BPA to the pregnant rats. Part of radioactivity was transferred to neonatal rats from the milk of the treated lactating dam and remained in the intestine of the neonates after 24-h nursing by an untreated dam.     

Physiological disposition of CGS 16617 in rat, dog, and man

The disposition and metabolism of CGS 16617 (3-[(5-amino-1-carboxy-1S-pentyl)amino],2,3,4,5-tetrahydro-2-oxo-3S-1H-1 - benzazepine-1-acetic acid), and angiotensin l-converting enzyme inhibitor, were investigated in rats, dogs, and man. In rats, a single oral dose of 10 mg/kg 14C-CGS 16617 afforded peak plasma concentrations of drug between 0.5 and 6 hr of dosing. The AUC was on average 9.6% of that after iv administration of the same dose, indicating low oral absorption of the drug. The apparent volumes of distribution, V1 and Vdss, were 0.45 and 2.5 liters/kg, respectively. Disappearance of the drug from plasma after the iv dose was biphasic, with mean half-lives of 0.5 and 13 hr, respectively, for the lambda 1 and lambda 2 phases. After single iv doses (10 mg/kg) to dogs and rats, 14CGS 16617 was almost exclusively eliminated by the renal route, with urinary recoveries of greater than 90% of dose. The same dose administered orally gave urinary recoveries of less than 10% of the dose in rats and about 15% in the dog. The remainder of the dose was eliminated in the feces. Bile duct-cannulated rats excreted less than 3% of an oral 10 mg/kg dose in the bile, in 24 hr. In man (N = 4), a single oral dose of 100 mg 14C-CGS 16617 resulted in peak plasma concentrations of 0.02-0.07 microgram of drug eq/ml between 4 and 6 hr of dosing. The mean terminal half-life was estimated at 81 hr.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biotransformation and mass balance of faldaprevir,a hepatitis C NS3/NS4 protease inhibitor in rats

Abstract

1.?The metabolism, pharmacokinetics, excretion and tissue distribution of a hepatitis C NS3/NS4 protease inhibitor, faldaprevir, were studied in rats following a single 2?mg/kg intravenous or 10?mg/kg oral administration of [¹⁴C]-faldaprevir.

2.?Following intravenous dosing, the terminal elimination t_1/2 of plasma radioactivity was 1.75?h (males) and 1.74?h (females). Corresponding AUC_0–∞, CL and V_ss were 1920 and 1900?ngEq?·?h/mL, 18.3 and 17.7?mL/min/kg and 2.32 and 2.12?mL/kg for males and females, respectively.

3.?After oral dosing, t_1/2 and AUC_0–∞ for plasma radioactivity were 1.67 and 1.77?h and 11?300 and 17?900 ngEq?·?h/mL for males and females, respectively.

4.?In intact rats, ≥90.17% dose was recovered in feces and only ≤1.08% dose was recovered in urine for both iv and oral doses. In bile cannulated rats, 54.95, 34.32 and 0.27% dose was recovered in feces, bile and urine, respectively.

5.?Glucuronidation plays a major role in the metabolism of faldaprevir with minimal Phase I metabolism.

6.?Radioactivity was rapidly distributed into tissues after the oral dose with peak concentrations of radioactivity in most tissues at 6?h post-dose. The highest levels of radioactivity were observed in liver, lung, kidney, small intestine and adrenal gland.     

Pharmacokinetics, tissue distribution, and excretion of sitafloxacin, a new fluoroquinolone antibiotic, in rats, dogs, and monkeys

The pharmacokinetics, tissue distribution and excretion of sitafloxacin (CAS 127254-12-0, DU-6859a) were investigated in rats, dogs, and monkeys following single intravenous or single oral administration of 14C-labelled sitafloxacin at a dose of 4.69 mg/kg. Following single administration of the oral dose, serum concentrations of radioactivity peaked at 0.5 h in rats, 2.3 h in dogs, and 2.5 h in monkeys. The apparent absorption ratios of 14C-sitafloxacin based on the AUC0-infinity were 31%, 51%, and 93% in rats, dogs, and monkeys, respectively. In rats, the drug-related radioactivity had been distributed to most organs and tissues 30 min after oral dosing, and had been essentially eliminated after 24 h. The highest levels of radioactivity were observed in the kidneys and liver, whereas the concentrations in the cerebrum and spinal cord were much lower than the serum value. The urinary recoveries of radioactivity after intravenous dosing were 45.5 % in rats, 32.3 % in dogs, and 77.8 % in monkeys. In bile duct-cannulated rats, 57.8 % of the orally administered radioactivity was excreted in the bile within 48 h, and at least 45 % of the sitafloxacin-related material secreted in the bile was re-absorbed from the gastrointestinal tract. These results indicate that sitafloxacin is rapidly absorbed and widely distributed into various tissues. Sitafloxacin-related material is eliminated primarily through both renal and biliary excretion in rats, and possibly in dogs, whereas renal excretion is the major route of elimination in monkeys.     

Absorption,distribution and excretion of nilvadipine,a new dihydropyridine calcium antagonist,in rats and dogs

1. The absorption, distribution and excretion of nilvadipine have been studied in male rats and dogs after an i.v. (1 mg/kg for rats, 0.1 mg/kg for dogs) and oral dose (10 mg/kg for rats, 1 mg/kg for dogs) of ¹⁴C-nilvadipine.

2. Nilvadipine was rapidly and almost completely absorbed after oral dosing in both species; oral bioavailability was 4.3% in rats and 37.0% in dogs due to extensive first-pass metabolism. The ratios of unchanged drug to radioactivity in plasma after oral dosing were 0.4–3.5% in rats and 10.4–22.6% in dogs. The half-lives of radioactivity in plasma after i.v. and oral dosing were similar, i.e. 8–10h in rats, estimated from 2 to 24 h after dosing and 1.5 d in dogs, estimated from 1 to 3 d. In contrast, plasma concentrations of unchanged drug after i.v. dosing declined biexponentially with terminal phase half-lives of 1.2 h in rats and 4.4 h in dogs.

3. After i.v. dosing to rats, radioactivity was rapidly distributed to various tissues, and maintained in high concentrations in the liver and kidneys. In contrast, after oral dosing to rats, radioactivity was distributed mainly in liver and kidneys.

4. With both routes of dosing, urinary excretion of radioactivity was 21–24% dose in rats and 56–61% in dogs, mainly in 24 h. After i.v. dosing to bile duct-cannulated rats, 75% of the radioactive dose was excreted in the bile. Only traces of unchanged drug were excreted in urine and bile.     

Disposition of 2-mercaptobenzothiazole and 2-mercaptobenzothiazole disulfide in rats dosed intravenously, orally, and topically and in guinea pigs dosed topically

To determine the metabolic disposition of [14C]-2-mercaptobenzothiazole (MBT) and [14C]-2-mercaptobenzothiazole disulfide (MBTS), male and female rats were dosed topically. Topical doses were 36.1 micrograms/animal for [14C]MBT and 33.6 micrograms/animal for [14C]MBTS. Although more MBT passed through the skin than MBTS and although, relative to rats, guinea pigs absorbed a greater percentage of the dose (33.4% compared to 16.1-17.5% of the MBT and 12.2% compared to 5.94-7.87% for MBTS), the disposition of radioactivity derived from the two compounds was similar. Washing of the skin removed more of the radioactivity from guinea pigs than from rats. For both sexes of rats dosed intravenously with [14C]MBT (0.602 mg/kg) or [14C]MBTS (0.571 mg/kg), disposition of the compounds was similar. In 72 h, 90.9-101% of the dose appeared in the urine and 3.79-15.1% in the feces. At this time, a small portion of the administered radioactivity (1.52-1.96% of the dose) remained associated with erythrocytes. Oral dosing of rats for 14 d with unlabeled MBT (0.510 mg/kg.d) prior to a single dose of [14C]MBT (0.503 mg/kg) or with unlabeled MBTS (0.521 mg/kg.d) prior to a single dose of [14C]MBTS (0.730 mg/kg). For both sexes, disposition of the compounds was similar. At 96 h after dosing, a small portion of the administered radioactivity (1.20-1.69% of the dose) remained associated with erythrocytes, most of which was bound to the membranes. For both compounds and sexes, 60.8-101% of the radioactivity administered appeared in the urine and 3.46-9.99% in the feces in 96 h. At the time, only trace amounts of radioactivity remained in tissues other than blood. Of these tissues, thyroid contained the highest concentration. In the urine, there was a detectable MBT or MBTS, but there were two metabolites, one of which was identified as a thioglucuronide derivative of MBT. The other was possibly a sulfonic acid derivative of MBT. In conclusion, there were similarities in absorption, distribution, and metabolism of [14C]MBT and [14C]MBTS in rats and in guinea pigs, indicating that [14C]MBTS was readily converted to [14C]MBT.     

Disposition of 2-(2-quinolyl)-1,3-indandione (D. C. yellow #11) in rats dosed orally or intravenously

The disposition of 2-(2-quinolyl)-1,3-indandione (D. C. yellow #11, DCY) in male Fischer rats dosed intravenously or by feeding was determined. For rats given [14C]DCY in the feed (0.00044-0.41% of the diet), recovery of radioactivity during the 24-h dosing period and the 72-h period thereafter ranged from 89.1 to 93.9% for feces and from 4.98 to 6.25 for urine. Tissues contained only trace amounts. Following intravenous dosing with [14C]DCY (0.93 mg/kg), radioactivity distributed readily into most tissues; maximum amounts were present at 5 min, the earliest time of assay. Maximum amounts of radioactivity in fat, skin, and gut tissue, however, were present at 30 min after dosing. These three tissues also had relatively long alpha phases for the elimination of radioactivity. In 24 h after intravenous dosing, rats excreted 81.1% of the dose in the feces and 16.0% of the dose in the urine. For rats fitted with biliary cannulas, 54.5% of the dose, all of which was metabolites of [14C]DCY, was recovered in the bile in 4 h. Associated with the rapid and extensive biliary excretion of metabolites of intravenously administered [14C]DCY was the appearance of large amounts of radioactivity in the feces and also, at intermediate time points, in the liver, gut contents, and gut tissue. In conclusion, rats rapidly distribute, metabolize, and excrete [14C]DCY.     

The disposition of radioactivity after administration of the anthelminthic methyl-14C-5-cyclopropylcarbonyl-2-benzimidazole carbamate (ciclobendazole) to rats and dogs

1. The disposition of radioactivity has been studied in rats and dogs after administration of a new anthelminthic agent, 14C-labelled methyl-5-cyclopropylcarbonyl-2-benzimidazole carbamate (14C-ciclobendazole). 2. An oral dose of 14C-ciclobendazole (4 mg/kg) to rats was rapidly absorbed and about 70% and 20% of the dose was excreted in the faeces and urine, respectively, during 2 days. Bile duct cannulated rats excreted about 80% of the dose in 48-h bile, about 2% in the faeces and about 10% in the urine showing that an oral dose was well-absorbed and that some enterohepatic circulation probably occurred. The excretion of radioactivity in the bile was less after i.v. administration. 3. An oral dose of 14C-ciclobendazole (4 mg/kg) to dogs was mainly eliminated during 2 days with about 80% of the dose in the faeces and only about 10% in the urine. Anaesthetised bile duct-cannulated dogs, excreted between 26% and 35% of an oral dose in the bile during 24 h and up to 58% of an oral dose was absorbed at this time. 4. The tissue distribution of radioactivity in rats and dogs after single or multiple oral doses of 14C-ciclobendazole (4 mg/kg) showed that there was no unusual accumulation or localisation of radioactivity in the measured tissues. Highest concentrations were present in the intestinal tract, liver and kidneys, organs associated with biotransformation and excretion and also in the lungs and adrenals. 5. After oral administration of 14C-ciclobendazole to rate at three different dose levels (4, 40 and 400 mg/kg), peak plasma levels occurred at 15-30 min and declined with similar half-lives (about 20 h). A comparison of peak concentrations and areas under the plasma concentration-time relationships showed that the absorption of ciclobendazole was probably dose-dependent, a lower proportion probably being absorbed at higher doses. After repeated daily oral dosing with 14C-ciclobendazole (4 mg/kg), there were no significant changes in either the daily plasma concentrations or the biological half-life measured after the last dose, indicating that ciclobendazole probably did not induce or inhibit its own metabolism when dosed repeatedly at 4 mg/kg. 6. A comparison of the areas under the plasma concentration-time relationships after oral, i.p. and i.v. administration of 14C-ciclobendazole to rates indicated that there was no signigicant uptake by the liver during first pass and that an oral dose was well absorbed by rats. 7. The peak plasma concentration in the dog, after an oral dose of 14C-ciclobendazole (4 mg/kg) was reached at about 30 min and declined with a half-life of about 3 h. 8. Ciclobendazole was probably well-absorbed by rats and dogs and excreted more rapidly by the latter species than by the former Relatively higher plasma concentrations of drug and/or metabolites were thus achieved in rats than in dogs.     

Age-related changes in the disposition of benzyl acetate. A model compound for glycine conjugation

The in vivo metabolism and excretion of benzyl acetate (BA), a model compound for glycine conjugation, was examined in male Fischer 344 rats and C57BL/6N mice. Rats aged 3-4, 9, and 25 months received a single oral dose of either 5 or 500 mg/kg 14C-BA, while male mice aged 2, 13, and 25 months received a single oral dose of 10 mg/kg 14C-BA. Urine and feces were collected for 96 hr. Biliary excretion and plasma elimination were also examined in male Fischer rats after iv administration of 5 mg/kg 14C-BA. In both young and old rats and mice, hippuric acid (HA) was the major urinary metabolite after oral dosing of BA. No significant age-related difference was observed in rats in the urinary elimination of BA-derived radioactivity or in the percentage of the total dose excreted as hippuric acid (approximately 95%). Twenty-five-month old rats excreted a significantly higher percentage of the total dose as benzyl mercapturic acid (approximately 2%) than did 3- to 4-month-old rats (approximately 1%) at the 5 mg dose. Benzyl mercapturic acid excretion in 3- to 4-month-old rats was also increased significantly at 500 mg/kg BA vs. 5 mg/kg BA. Fecal excretion of BA-derived radioactivity declined significantly in 25-month-old rats at both the 5 and 500 mg dose. This decrease was reflected by an age-related decline in biliary excretion and higher plasma levels of BA-derived radioactivity. Examination of plasma metabolites revealed a significantly higher level of HA and benzoyl glucuronide in 25-month rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism and disposition of bisphenol A in female rats

Bisphenol A (BPA), which is used in the manufacture of polycarbonates, elicits weak estrogenic activity in in vitro and in vivo test systems. The objectives of this study were to compare the patterns of disposition of radioactivity in adult female F-344 and CD rats after oral administration of (14)C BPA (100 mg/kg), to isolate the glucuronide of BPA and to assess its estrogenic activity in vitro, and to evaluate the transfer of radioactivity to pups from lactating dams administered (14)C BPA. Over 6 days, F-344 rats excreted more radioactivity in urine than CD rats. The major metabolite in urine was identified as bisphenol A glucuronide (BPA gluc) by incubation with beta-glucuronidase and (1)H and (13)C NMR spectroscopy. In lactating CD rats administered (14)C BPA (100 mg/kg) by gavage, only a small fraction of the label was found in milk, with 0.95 +/- 0.66, 0.63 +/- 0.13, and 0.26 +/- 0.10 microg equiv/ml (mean +/- SD) from dams collected 1, 8, and 26 h after dosing, respectively. Radioactivity in pup carcasses indicated exposure in the range of microgram equivalents per kilogram; those values ranged from 44.3 +/- 24.4 for pups separated from their lactating dams at 2 h to 78.4 +/- 10.9 at 24 h. BPA gluc was the prominent metabolite in milk and plasma. In test systems for activation of in vitro estrogen receptors alpha and beta, BPA gluc did not show appreciable efficacy at concentrations up to 0.03 mM, indicating that metabolism via glucuronidation is a detoxication reaction.     

The metabolism and excretion of carbovir, a carbocyclic nucleoside, in the rat

The metabolism and disposition of carbovir [(1R-cis)-2-amino 1,9-(4-(hydroxymethyl)-2-cyclopenten-1-yl)-6H-purin-6-one], an antiviral agent, was examined in rats using an isolated perfused liver, and in vivo following iv and po administration at two dosing levels. HPLC analysis of perfusate and bile after perfusion of the isolated liver with racemic (+/-)[8-3H]carbovir showed conversion to two major metabolites. The major component in the bile was shown to be a glucuronide conjugate of carbovir. The perfusate contained a single major component that was isolated and identified as the 4'-carboxylic acid derivative. In vivo excretion balance studies were conducted with [8-14C](-)-carbovir using four animals in each dosing group. Following iv administration at 10 mg/kg doses, the majority of the dose (77%) was excreted in the urine. At 60 mg/kg iv dosing, this value dropped to 42% (the remainder appearing in the feces). With po administration at both doses, the bulk of the dose (41-61%) was excreted in the feces. HPLC profiling of the urine showed that in all cases, most of the radioactivity was accounted for as carbovir and the 4'-acid metabolite. This metabolite accounted for up to 25% of the administered dose following 60 mg/kg iv administration, and less than 3% following 10 mg/kg po dosing. A second urinary metabolite accounting for up to 5% of the dose also was seen in all samples. This was isolated and identified as the trans-diastereomer of the 4'-acid (resulting from epimerization at the 4' position).(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism and pharmacokinetics of bisphenol A (BPA) and the embryo-fetal distribution of BPA and BPA-monoglucuronide in CD Sprague-Dawley rats at three gestational stages.

The pharmacokinetics of bisphenol A (BPA), including the quantification of the major BPA metabolite BPA-monoglucuronide conjugate (BPA-glucuronide) was studied in Sprague-Dawley rats at different stages of gestation. 14C-BPA was administered orally at 10 mg BPA/kg body weight (0.2 mCi/rat) to nongravid rats and to other groups on gestation days (GD) 6, 14, and 17. GD 0 was when the vaginal smear was sperm positive or a copulatory plug was observed. Radioactivity derived from 14C-BPA was quantified in the maternal blood, selected tissues, and the embryo or fetus. BPA and BPA-glucuronide were quantified in maternal plasma and excreta. Additional rats were dosed orally at 10 mg 14C-BPA/kg (0.2 mCi/rat or 0.5 mCi/rat) on GD 11, 13, and 16 to further study the distribution of BPA and BPA-glucuronide to the embryo/fetal tissue. The tissue distribution, metabolism, or the rates or routes of excretion of BPA, or the plasma concentration-time profiles of BPA-glucuronide did not appear to be altered at any stage of gestation as compared to nonpregnant rats. In the GD 11 group, neither BPA nor BPA-glucuronide was detected in the yolk sacs or embryos, except for trace concentrations of BPA-glucuronide in the yolk sacs at 15 min postdosing. In the GD 13 group, both BPA and BPA-glucuronide were detected in the yolk sacs of the conceptus but not in the embryos/fetuses, except for BPA at 15 min. For the animals dosed with 0.2 mCi/rat on GD 16, both analytes were detected in the placentae at 15 min and 12 h, but not at 96 h. Traces of both analytes were detected in fetal tissue in two of five specimens at 15 min only. In rats dosed on GD 16 with 0.5 mCi/rat, the BPA-glucuronide and BPA concentrations in maternal plasma at 15 min were 1.7 and 0.06 mug equivalents (eq)/g plasma, respectively. At the same time postdosing in these animals, the placental BPA-glucuronide concentrations were lower (0.34 mug eq BPA [as glucuronide]/g), and the BPA concentrations were about equivalent (0.095 mug/g). Fetal BPA-glucuronide and BPA concentrations were markedly lower, 0.013 and 0.018 mug eq/g, respectively. Therefore, no selective affinity of either yolk sac/placenta or embryo/fetus for BPA or BPA metabolites relative to maternal plasma or tissues was observed in this study.     

Absorption, distribution, metabolism and excretion of intravenously and dermally administered triethanolamine in mice.

Triethanolamine (TEA) is an amino alcohol having widespread applications in consumer goods and as an industrial chemical. A number of relatively high-dose dermal toxicity studies have been conducted in rats and mice reflecting the principal route of human exposure to TEA. The absorption, distribution, metabolism and excretion (ADME) of (14)C-TEA derived radioactivity were determined in male C3H/HeJ mice following dermal application of 2000 mg/kg (neat) or, to characterize blood kinetics, intravenous (iv) injection of 1 mg/kg (14)C-TEA. Balance and excretion data were also collected in mice utilizing several dermal dosing scenarios (1000 mg/kg in acetone, 2000 mg/kg neat, 2000 mg/kg in water) and, for comparative purposes, in male Fischer 344 rats dosed dermally with 1000 mg/kg neat (14)C-TEA. Urine, feces, expired CO(2) (iv) and, where appropriate, blood were collected over a 24- or 48-hour period post-dosing. The half-life for dermal absorption of radioactivity was estimated to be 1.3 hours. Intravenously administered radioactivity was eliminated in a biphasic manner with a prominent initial phase (half-life of 0.3 hr) followed by a slower terminal phase (half-life of 10 hr). Radioactivity was excreted primarily via the urine (49-69%) as unmetabolized TEA, regardless of dosage, route or vehicle used. Fecal excretion of radioactivity comprised 16-28% of dose administered. The body burden at sacrifice (sum of liver, kidney, carcass and non-application site skin) ranged from 3 to 6% of the dose. It was concluded that TEA is absorbed extensively following dermal application to mice at dosages relevant to toxicity testing and that acetone or water vehicles do not appear to significantly alter total uptake. Significantly, the blood kinetics and ADME of TEA in mice and/or rats differs from that of a related chemical, diethanolamine, which appears to be more toxic to rodents than TEA.     

The absorption, distribution, metabolism and elimination of bevirimat in rats

Bevirimat is the first drug in the class of maturation inhibitors, which treat HIV infection by disrupting the activity of HIV protease enzyme with a mechanism of action distinct from that of conventional protease inhibitors. The absorption, distribution, metabolism and elimination characteristics of single intravenous (25 mg/kg) and oral (25 mg/kg and 600 mg/kg) doses of 14C-bevirimat were studied in male Sprague Dawley and Long Evans rats. Pharmacokinetic and mass-balance studies revealed that bevirimat was cleared rapidly (within 12-24 h) after dosing, although plasma radioactivity was quantifiable up to 168 h. Radioactive metabolites of bevirimat were responsible for approximately 60-80% of plasma radioactivity. Systemically available bevirimat was predominantly (97%) excreted via bile in the faeces, with 相似文献   

Disposition of radiolabeled ifetroban in rats, dogs, monkeys, and humans.

Ifetroban is a potent and selective thromboxane receptor antagonist. This study was conducted to characterize the pharmacokinetics, absolute bioavailability, and disposition of ifetroban after i.v. and oral administrations of [14C]ifetroban or [3H]ifetroban in rats (3 mg/kg), dogs (1 mg/kg), monkeys (1 mg/kg), and humans (50 mg). The drug was rapidly absorbed after oral administration, with peak plasma concentrations occurring between 5 and 20 min across species. Plasma terminal elimination half-life was approximately 8 h in rats, approximately 20 h in dogs, approximately 27 h in monkeys, and approximately 22 h in humans. Based on the steady-state volume of distribution, the drug was extensively distributed in tissues. Absolute bioavailability was 25, 35, 23, and 48% in rats, dogs, monkeys, and humans, respectively. Renal excretion was a minor route of elimination in all species, with the majority of the dose being excreted into the feces. After a single oral dose, urinary excretion accounted for 3% of the administered dose in rats and dogs, 14% in monkeys, and 27% in humans, with the remainder excreted in the feces. Extensive biliary excretion was observed in rats with the hydroxylated metabolite at the C-14 position being the major metabolite observed in rat bile. Ifetroban was extensively metabolized after oral administration. Approximately 40 to 50% of the radioactivity in rat and dog plasma was accounted for by parent drug whereas, in humans, approximately 60% of the plasma radioactivity was accounted for by ifetroban acylglucuronide.