Pharmacokinetics of epinastine and a possible mechanism for double peaks in oral plasma concentration profiles.

The pharmacokinetics of epinastine (EPN), an anti-allergic agent, was investigated in rats. The plasma concentration-time profile of EPN after intravenous (i.v.) administration was triexponential. After oral administration of EPN (7.5 and 20 mg/kg), the drug was rapidly absorbed, and Cmax was reached 2 h after dosing. A minor secondary peak was observed in EPN plasma concentration-time profiles at both doses. The bioavailability of EPN after oral dosing was 41 and 40%. The kinetic parameters (T 1/2, AUC and MRT) for unlabeled EPN were much smaller than those for 14C-EPN, which has already been reported. The total biliary excretion of EPN at a 7.5 mg/kg dose was 15.5% of the dose, but the percentage of conjugates in bile was extremely low and about 11% of the total biliary excretion. The increase in the plasma concentration in bile duct-linked rats after oral administration of EPN (20 mg/kg) was not observed, indicating that a secondary increase in drug concentration based on enterohepatic circulation was ruled out. When the gastrointestinal (GI)-transit of phenol red (PR) after oral administration of EPN (20 mg/kg) was estimated, the GI-transit of PR was significantly delayed, and at 3-4 h after dosing half of the PR dose reached the jejunum. The remaining EPN in the small intestine after oral administration (7.5 mg/kg) reached peak levels 2 h after dosing, but then partly increased again at 4 h. As a result, it was clarified that the double peaks observed after oral doses are mainly due to the delayed absorption of a part of EPN, based on the reduction in gastric motility caused by the drug.     

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.     

Pharmacokinetics and disposition of the novel dopamine agonist Z-7760 in rat after intravenous and oral administration

1. Z-7760 (S(-)-N-[N-2-phenylethyl)-6-hexylamino]-N-propyl-5,6-dihydroxy-1,2,3,4-tetrahydro-2-naphthylamine dihydrobromide) is a potent dopamine D-1 and D-2 agonist synthesized during a search for agents to treat heart failure. Reported is the fate of the drug in rat. 2. 3H-Z-7760 was administered p.o. and i.v. to male Sprague-Dawley rats (0.4 mg and 400 microCi/kg in 0.1% ascorbic acid) and venous blood samples collected at intervals up to 48 h. Comparison of the AUC for total 3H showed that 37% of an oral dose of Z-7760 was absorbed. The percentage plasma 3H present as the parent compound fell from 82% 30 min after i.v. dosing to 12% after 24 h. After oral dosing, the fraction of plasma 3H present as unchanged Z-7760 was < 5% and this was essentially unaltered throughout the study. The long terminal elimination phase evident from 6 h was notable after both routes of administration. 3. The bile duct-cannulated rat was given 3H-Z-7760 p.o. (0.4 mg and 40 microCi/kg) and bile was collected for up to 22 h. Biliary excretion accounted for 30% of the dose. No parent compound was detected in the bile. 4. In further studies, other rats were dosed p.o. or i.v. with 3H-Z-7760 (0.4 mg and 400 microCi/kg) and urine and faeces were collected daily for 3 days. The major route of excretion was the faeces with 94-97% 3H recovered after oral and 70-73% after i.v. dosing. A further 4-7% was recovered in the urine after oral and 12-13% after i.v. dosing. 5. After oral administration of Z-7760 (100 mg/kg, 40 microCi/kg) to rats, the major metabolites in the urine were identified as the 5-O-methyl and glucuronic acid conjugates of Z-7760 by LC and MS. The glucuronide was only seen in urine after oral administration but 5-O-methyl-Z-7760 was present in urine and faeces after both routes of administration. 6. The low bioavailability of Z-7760 is the consequence of its poor absorption from the gastrointestinal tract as well as extensive first-pass metabolism that further reduces systemic blood concentrations after oral administration.     

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.     

Studies of the metabolism and excretion of silybin in the rat]

The metabolism and excretion of silybin (as N-methyl-glucamine salt) was investigated after intravenous and oral administration to rats. In the urine, silybin was excreted mostly in the unchanged form after intravenous as well as oral application, whilst in the bile it appeared above all in the form of metabolites. By hydrolysis with arylsulfatase/beta-glucuronidase, the metabolites were identified as sulfate and glucuronide conjugates of silybin and dehyrosilybin; the latter appeared in small quantities as a dehydrated product of silybin. After intravenous injection of 20 mg silybin per kg body weight, the excreted amount of silybin after 48 h was 8%, whereas 76% was eliminated in the bile within the same period of time. After oral application of 2--20 mg silybin/kg body weight 20% after 40 mg/kg 35% and after 120 mg/kg 20% of the administered silybin was excreted in the bile during 48 h. The maximum excretion rate was achieved at application of 20 mg/kg p.o. after 1 h. At this dosage, 2--5% was eliminated within the same time in the urine. The excretion of silybin mainly took place (more than 80% of the total of excreted bilybin) in the bile, both after oral and intravenous administration.     

The fate of saccharin impurities: the excretion and metabolism of [3-14C]Benz[d]-isothiazoline-1,1-dioxide (BIT) in man and rat

1. The 14C label of [3-14C]benz[d]isothiazoline-1,1-dioxide (BIT) (40 mg/kg) was rapidly eliminated (97% dose in 24 h), largely in the urine (92% dose in 24 h), after oral administration to rats. Larger doses (400 mg/kg) were eliminated more slowly after oral or parenteral administration (45--60% within 24 h) mostly in the urine (42--53%). Little 14C (2--3% dose) was present in the faeces after intraperitoneal (400 mg/kg) or low oral (40 mg/kg) doses, but the presence of larger amounts (12% dose) after larger oral doses (400 mg/kg) indicated incomplete absorption. 2. Metabolites identified in the urine of rats were saccharin (about 30% of urinary 14C), 2-sulphamoylbenzoic acid (about 35% urinary 14C) and 2-sulphamoylbenzyl alcohol (15% urinary 14C) in addition to unchanged compound (5--10% urinary 14C). The urine also contained a polar, labile metabolite that gave BIT on acid hydrolysis. The pattern of metabolism was not significantly affected by dose or route of administration. 3. In man, urine was the major route of elimination of 14C (93% dose) after administration of 14C-BIT (0.5 mg/kg). Negligible 14C was recovered in the faeces (less than 1% dose). Excretion was rapid (59% dose in 6 h; 80% dose in 12 h) and little 14C was eliminated on the second (3%) or subsequent days after dosing. 4. Identified metabolites in man included saccharin (about 50% of urinary 14C), 2-sulphamoylbenzoic acid (7% urinary 14C) and 2-sulphamoylbenzyl alcohol (8% urinary 14C unconjugated and 40% conjugated) with negligible unchanged compound. Only traces of the polar labile metabolite were detected. 5. the possible significance of metabolic interrelationships of toluene-2-sulphonamide and BIT to studies on the metabolism of saccharin are discussed.     

Pharmacokinetics of L-FMAUS, a new antiviral agent, after intravenous and oral administration to rats: contribution of gastrointestinal first-pass effect to low bioavailability

The pharmacokinetics of L-FMAUS after intravenous and oral administration (20, 50 and 100 mg/kg) to rats, gastrointestinal first-pass effect of L-FMAUS (50 mg/kg) in rats, in vitro stability of L-FMAUS, blood partition of L-FMAUS between plasma and blood cells of rat blood, and protein binding of L-FMAUS to 4% human serum albumin were evaluated. L-FMAUS is being evaluated in a preclinical study as a novel antiviral agent. Although the dose-normalized AUC values of L-FMAUS were not significantly different among the three doses after intravenous and oral administration, no trend was apparent between the dose and dose-normalized AUC. After oral administration of L-FMAUS (50 mg/kg), approximately 2.37% of the oral dose was not absorbed, and the extent of absolute oral bioavailability (F) was approximately 11.5%. The gastrointestinal first-pass effect was approximately 85% of the oral dose. The first-pass effects of L-FMAUS in the lung, heart and liver were almost negligible, if any, in rats. Hence, the small F of L-FMAUS in rats was mainly due to the considerable gastrointestinal first-pass effect. L-FMAUS was stable in rat gastric juices. The plasma-to-blood cells partition ratio of L-FMAUS was 2.17 in rat blood. The plasma protein binding of L-FMAUS in rats was 98.6%.     

Disposition of a low dose of 14C-bisphenol A in male rats and its main biliary excretion as BPA glucuronide.

Bisphenol A (BPA) is a weak xenoestrogen mass-produced with potential human exposure. The disposition of bisphenol A in male Fischer-344 (F344) rats dosed orally (100 or 0.10 mg/kg) or intravenously (0.10 mg/kg) was determined. Smaller amounts of the dose appeared in the urine. The main excretion route was feces in rats irrespective of dose and administration route. The biliary excretion during 6 h was 58-66% after iv dosing and 45-50% after oral dosing at 0.10 mg 14C-BPA/kg. Toxicokinetic parameters obtained from 14C-BPA-derived radioactivity in blood were the terminal elimination half-life, t1/2beta = 39.5 h, and total body clearance, CLtot = 0.52 l/h/kg after iv dosing of 0.10 mg 14C-BPA/kg to male rats. The blood concentration reached its maximum of 5.5 ng-eq/ml at 0.38 h after oral dose. AUC(0-6 h), AUC(0-48 h), and AUCinf of 14C-BPA-derived radioactivity, were 34, 118, and 192 ng-eqh/ml for the iv dose and 18, 102, and 185 ng-eqh/ml for the oral dose, respectively. The oral bioavailability of F(0-6 h), F(0-48 h), and Finf were 0.54, 0.86, and 0.97, respectively. The 14C-BPA-derived radioactivity was strongly bound to plasma protein (free fraction, fu = 0.046) and preferentially distributed to the plasma with a blood/plasma ratio of 0.67. From the bile of male rats orally dosed at 100 mg/kg, we have isolated and characterized BPA glucuronide (BPA-gluc) by ESI/MS, 1H and 13C NMR spectroscopy. HPLC analysis showed that BPA-gluc was the predominant metabolite in bile and urine. Unchanged BPA was mostly detected in feces. These results suggest that BPA is mainly metabolized to BPA-gluc and excreted into feces through the bile and subject to enterohepatic circulation in rats irrespective of dose and administration route.     

Oral bioavailability and enterohepatic recirculation of otilonium bromide in rats

This study was conducted to examine the oral bioavailability and the possibility of enterohepatic recirculation of otilonium bromide in rats. A sensitive LC/MS/MS assay (LLOQ 0.5 ng/mL) was developed for the determination of otilonium and applied to i.v. and oral administration studies in bile duct cannulated (BDC) and non-BDC rats. After i.v. injection to BDC rats (1 mg/kg as otilonium), average t_1/2, CL, V_z and AUC were 7.9 ± 1.9 h, 8.7 ± 3.1 mL/min/kg, 5.7 ± 1.4 L/kg and 2,088 ± 676 ng·h/mL, respectively, and these values were comparable to those found in non-BDC rats. The percentages of i.v. dose excreted unchanged in bile and urine in BDC rats were 11.6 ± 3.0 and 3.1 ± 0.7%, respectively. Upon oral administration to non-BDC rats (20 mg/kg as otilonium), t_1/2, C_max, T_max and AUC were 6.4 ± 1.3 h, 182.8 ± 44.6 ng/mL, 1.9 ± 1.6 h and 579 ± 113 ng·h/mL, respectively. The absolute oral bioavailability was low (1.1%), while the drug was preferentially distributed to gastrointestinal tissues. A secondary peak was observed in the serum concentration-time profiles in non-BDC rats following both i.v. and oral administration, indicating that otilonium bromide was subject to enterohepatic recirculation.     

Absorption,distribution, metabolism and excretion of telmesteine,a mucolitic agent,in rat

1. The metabolism and disposition of telmesteine, a muco-active agent, have been investigated following single oral or intravenous administration of (14)C-telmesteine in the Sprague-Dawley rat. 2. (14)C-telmesteine was rapidly absorbed after oral dosing (20 and 50 mg kg(-1)) with an oral bioavailability of >90% both in male and female rats. The C(max) and area under the curve of the radioactivity in plasma increased proportionally to the administered dose and those values in female rats were 30% higher than in male rats. 3. Telmesteine was distributed over all organs except for brain and the tissue/plasma ratio of the radioactivity 30 min after dosing was relatively low with a range of 0.1-0.8 except for excretory organs. 4. Excretion of the radioactivity was 86% of the dose in the urine and 0.6% in the faeces up to 7 days after oral administration. Biliary excretion of the radioactivity in bile duct-cannulated rats was about 3% for the first 24 h. The unchanged compound mainly accounted for the radioactivity in the urine and plasma. 5. Telmesteine was hardly metabolized in microsomal incubations. A glucuronide conjugate was detected in the urine and bile, but the amount of glucuronide was less than 6% of excreted radioactivity.     

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.     

Absorption, protein binding, pharmacokinetics and excretion of the anti-ischemic and anti-hypertensive arylpiperazine derivative CDRI-93/478 in rats

CDRI-93/478 (1- [4-(4-fluorophenyl) piperazine-1-yl]-3-(2-oxopyrrolidin-1-yl) propane hydrochloride, an arylpiperazine derivative, is a potent anti-ischemic and anti-hypertensive agent and is in advanced stage of preclinical trials. In order to develop CDRI-93/478 into a clinical agent, the absorption, protein binding, pharmacokinetics, and excretion of the compound were investigated in male Sprague-Dawley rats. Oral absorption was evaluated in situ and in vivo, using the portal-venous concentration difference method. The compound showed negligible absorption (ka = 0.01 h(-1)) at pH 2.6. However, the rate of absorption of the compound at pH 7.4 was 0.6 h(-1) and was comparable to that observed in the in vivo study (ka, >0.58 h(-1)) in rats after a single 2 mg/kg oral dose. In vitro and in vivo protein binding studies using the ultrafiltration method showed that the compound was subject to low protein binding (<40%) and was independent of the substrate concentration over a range of 1-16 microg/ml. Pharmacokinetic parameters of the compound were determined after intravenous and oral administration of 0.6, 2 and 8 mg/kg doses using a model independent method. After oral administration, the compound showed the double-peak phenomenon, which could be due to the high water solubility (log P, 1.01 +/- 0.01), regional differences in the gastrointestinal absorption and enterohepatic recirculation effects. The absorption of CDRI-93/478 was rapid and showed a bioavailability of 69.9 +/- 5.1% (mean +/- S. D.) after 2 and 8 mg/kg oral dose. However, the pharmacokinetic parameters of the compound could not be determined after the 0.6 mg/kg oral dose due to insufficient data points. The studies following intravenous and oral administration demonstrated linear pharmacokinetics, low clearance and high volume of distribution over the dose range studied. The excretion studies after the 8 mg/kg oral dose indicated that the compound was not excreted through the feces and the urinary excretion was very low (<2%).     

Dose-independent pharmacokinetics of a new reversible proton pump inhibitor,KR-60436, after intravenous and oral administration to rats: gastrointestinal first-pass effect

Dose-independent pharmacokinetic parameters of KR-60436, a new proton pump inhibitor, were evaluated after intravenous (i.v.; 5, 10, and 20 mg/kg) and oral (20, 50, and 100 mg/kg) administration to rats. The hepatic, gastric, and intestinal first-pass effects were also measured after iv, intraportal (i.p.), intragastric (i.g.), and intraduodenal (id) administrations to rats of a dose of 20 mg/kg. The areas under the plasma concentration-time curve from time to zero to time infinity (AUCs) were independent of iv and oral dose ranges studied; the dose-normalized AUCs were 83.0-104 microg. min/mL (based on 5 mg/kg) and 78.4-96.8 microg. min/mL (based on 20 mg/kg) for iv and oral administration, respectively. After an oral administration at a dose of 20 mg/kg, approximately 3% of the oral dose was not absorbed, and the extent of absolute oral bioavaliability (F) was estimated to be 18.8%. The AUCs of KR-60436 after i.g. and i.d. administration at a dose of 20 mg/kg were significantly smaller (82.4 and 57.5% decrease, respectively) than that after an i.p. administration at a dose of 20 mg/kg, suggesting that gastrointestinal first-pass effect of KR-60436 was approximately 80% of oral dose in rats (the gastric first-pass effect was approximately 25%). After an i.p. administration at a dose of 20 mg/kg, the AUC was 77.6% of an iv administration, suggesting that hepatic first-pass effect was approximately 22% of KR-60436 absorbed into the portal vein. Note that the value of 22% was equivalent to approximately 4% of the oral dose. Because only 17% of oral dose was absorbed into the portal vein, the low F of KR-60436 in rats was mainly due to considerable gastrointestinal first-pass effect, which was approximately 80% (the gastric first-pass effect was approximately 25%) of oral dose.     

Pharmacokinetics and tissue distribution of rifametane, a new 3-azinomethyl-rifamycin derivative, in several animal species

Single and repeated dose experiments in mice, rats, dogs and monkeys are reported in this study to assess the pharmacokinetics and tissue distribution of rifametane, a new semi-synthetic rifamycin with the chemical formula 3-[(1-diethylaminoethylidene)azinomethyl]rifamycin SV (CAS 94168-98-6, SPA-S-565). All the kinetic tests were carried out in comparison with known rifamycin derivatives, as rifampicin (CAS 13292-46-1) or rifamycin SV (CAS 6998-60-3). Mice received single i.v. and oral administration of 10 mg/kg of rifametane or of rifampicin and serum samples were obtained up to 96 h after dosing. The two antibiotics showed similar peak of serum concentrations, but rifametane showed a longer half-life and higher AUC values. In an additional experiment, the tissue/serum ratio after the 10 mg/kg oral dose was lower than unity for lungs and kidneys, while the liver/serum ratio exceeded the unity at all sampling times. After 4 weeks of once weekly administration measurable serum and tissue concentrations were observed, and after twice weekly administration for the same time period some blood and tissue accumulation was seen. Rats were treated with a single intravenous injection of 20 mg/kg of rifametane or rifampicin and with single oral or i.m. administration of 60 mg/kg of rifametane or reference standards (rifampicin and rifamycin SV resp.), in two separate trials. The serum half-life of the test antibiotic after i.v. dose was 6 times longer than that of rifampicin and the serum concentrations of rifametane after oral and i.m. doses were higher and longer-lasting than those of the reference compounds. Repeated daily administrations of rifametane at three dose levels (3, 10, 30 mg/kg p.o.) for 4 weeks induced very high serum and liver concentrations. Dogs received a single oral dose of 1.25 mg/kg of rifametane or 2.5 mg/kg of rifampicin. The serum half-life of rifametane resulted 3 times longer than that of rifampicin. Remarkable serum and tissue concentrations were observed after 3-4 weeks of daily oral administration of rifametane at 3, 10, 30 mg/kg dose. Monkeys were given single oral or i.m. administration of 30 mg/kg of rifametane or reference standards (oral rifampicin and i.m. rifamycin SV). The serum concentrations after rifametane were higher and more sustained than those of reference compounds and the half-lives of the test antibiotic were about 2.5 (p.o.) to 6 times (i.m.) longer. The urine excretion of rifametane after a single intravenous dose in rats and a single oral dose in dogs was very low, while rifampicin had a little higher urine concentrations.     

Kinetics of monochloroacetic acid at subtoxic and toxic doses in rats after single oral and dermal administrations.

Rats were administered a single oral (10 [subtoxic] or 225 [toxic, LD20] mg/kg) or dermal (125 mg/kg, LD20) dose of 14C-monochloroacetic acid (MCA) and the time-course (0.25, 0.75, 2, 4, 8, 16, and 32 h postadministration) of radioactivity determined in plasma, tissues, and excreta. At the subtoxic oral dose, concentration of 14C-MCA peaked at 0.1% of dose by 2 h. Most tissue profiles of MCA paralleled that of plasma with few exceptions. At the toxic oral dose, tissue concentrations remained initially below those seen after the subtoxic dose, because stomach retained most of the toxic dose for up to 8 h. Peak plasma concentration was reached within 0.25 h without an apparent subsequent uptake phase. Most of the dermal dose rapidly penetrated into the skin (>95% within 0.25 h) and remained sequestered there and released slowly. Concentration in plasma peaked at 0.36% of dose by 0.75 h and remained constant for up to 4 h. Peak tissue concentrations were reached between 2 and 4 h. Within 0.75 h, 9% of the dermally absorbed dose was metabolized by liver and eliminated through bile, all of which was subsequently reabsorbed. Two percent of MCA appeared in colon by 0.75 h, apparently as a result of direct transport through GI-wall in retrograde movement. About 70-80% of radioactivity recovered from the small intestine of orally dosed rats was parent compound. Fecal elimination was negligible ( 400 and < 450) and 175 (LD50 145) mg/kg after oral and dermal exposure, respectively.     

Pharmacokinetics and disposition of the novel dopamine agonist Z-7760 in rat after intravenous and oral administration

1. Z-7760 (S(?)-N-[N-2-phenylethyl)-6-hexylamino]-N-propyl-5,6-dihydroxy- 1,2,3,4-tetrahydro-2-naphthylamine dihydrobromide) is a potent dopamine D-1 and D-2 agonist synthesized during a search for agents to treat heart failure. Reported is the fate of the drug in rat. 2. ³H-Z-7760 was administered p.o. and i.v. to male Sprague-Dawley rats (0.4 mg and 400 μCi/kg in 0.1% ascorbic acid) and venous blood samples collected at intervals up to 48 h. Comparison of the AUC for total ³H showed that 37% of an oral dose of Z-7760 was absorbed. The percentage plasma ³H present as the parent compound fell from 82% 30 min after i.v. dosing to 12% after 24 h. After oral dosing, the fraction of plasma ³H present as unchanged Z-7760 was < 5% and this was essentially unaltered throughout the study. The long terminal elimination phase evident from 6 h was notable after both routes of administration. 3. The bile duct-cannulated rat was given ³H-Z-7760 p.o. (0.4?mg and 40 μCi/kg) and bile was collected for up to 22 h. Biliary excretion accounted for 30% of the dose. No parent compound was detected in the bile. 4. In further studies, other rats were dosed p.o. or i.v. with ³H-Z-7760 (0.4?mg and 400 μCi/kg) and urine and faeces were collected daily for 3 days. The major route of excretion was the faeces with 94-97% ³H recovered after oral and 70-73% after i.v. dosing. A further 4-7% was recovered in the urine after oral and 12-13% after i.v. dosing. 5. After oral administration of Z-7760 (100?mg/kg, 40 μCi/kg) to rats, the major metabolites in the urine were identified as the 5-O-methyl and glucuronic acid conjugates of Z-7760 by LC and MS. The glucuronide was only seen in urine after oral administration but 5-O-methyl-Z-7760 was present in urine and faeces after both routes of administration. 6. The low bioavailability of Z-7760 is the consequence of its poor absorption from the gastrointestinal tract as well as extensive first-pass metabolism that further reduces systemic blood concentrations after oral administration.     

Pharmacokinetic study of triptolide, a constituent of immunosuppressive chinese herb medicine, in rats

Triptolide is a potential anti-immune agent, and has shown multi-organic toxicity, however its toxic mechanism remained undiscovered. This paper aimed at characterizing the pharmacokinetic profiles of triptolide in rats to provide the clue to approach the toxic mechanism. The absorption, distribution, metabolism and excretion of triptolide were investigated in male Sprague-Dawley rats after single doses of oral and i.v. administration. After oral administration of 0.6, 1.2 and 2.4 mg/kg, the concentration of triptolide in plasma reached the maximum within 15 min, and declined rapidly with an elimination half-life from 16.81 to 21.70 min. The triptolide kinetics was fitted into one-compartment model after i.v. administration. Oral absolute bioavailability was 72.08% at the dose of 0.6 mg/kg. Triptolide was also rapidly distributed and eliminated in all selected tissues. Less than 1% triptolide of the dose was recovered from the bile, urine or feces as parent drug within 48 h. While triptolide could not be detected in tissues and plasma at 4 h post dose, rats in the group C (oral: 1.2 mg/kg) and D (oral: 2.4 mg/kg) showed obvious toxic response to triptolide and some of rats even died out. It was indicated that triptolide was metabolized extensively, eliminated rapidly, and also showed that the toxicity produced by the triptolide was lag behind the exposure concentration.     

Systemic lanthanum is excreted in the bile of rats

Lanthanum carbonate is a non-calcium-based oral phosphate binder for the control of hyperphosphataemia in patients with chronic kidney disease Stage 5. As part of its pre-clinical safety evaluation, studies were conducted in rats to determine the extent of absorption and routes of excretion. Following oral gavage of a single 1500 mg/kg dose, the peak plasma lanthanum concentration was 1.04+/-0.31 ng/mL, 8 h post-dose. Lanthanum was almost completely bound to plasma proteins (>99.7%). Within 24h of administration of a single oral dose, 97.8+/-2.84% of the lanthanum was recovered in the faeces of rats. Comparing plasma exposure after oral and intravenous administration of lanthanum yielded an absolute oral bioavailability of 0.0007%. Following intravenous administration of lanthanum chloride (0.3 mg/kg), 74.1+/-5.82% of the dose (96.9+/-0.50% of recovered lanthanum) was excreted in faeces in 42 days, and in bile-duct cannulated rats, 10.0+/-2.46% of the dose (85.6+/-2.97% of recovered lanthanum) was excreted in bile in 5 days. Renal excretion was negligible, with <2% of the intravenous dose recovered in urine. These studies demonstrate that lanthanum undergoes extremely low intestinal absorption and that absorbed drug is predominantly excreted in the bile.     

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.     

Stereochemical pharmacokinetics of the 2-arylpropionic acid non-steroidal antiinflammatory drug flunoxaprofen in rats and in man

Stereospecific serum assays of the non-steroidal antiinflammatory drug flunoxaprofen (S(+)-2-(4-fluorophenyl)-a-methyl-5-benzoxazoleacetic acid, Priaxim) were performed in rats after the oral administration of 10 mg/kg b.w. of the different enantiomeric forms of the drug or of the racemate in order to establish the occurrence and the rate of biotransformation of R(-)-flunoxaprofen to the S(+)-enantiomer, which is the pharmacologically active form. Preliminary observations of the enantiomeric blood levels were also made in man after a single oral dose (100 mg) of R(-)-flunoxaprofen or of the racemate. Blood was withdrawn at different time intervals up to 120 h in rats and up to 48 h in man and serum levels of flunoxaprofen enantiomers were determined by a HPLC method. The results obtained in the rat show that S(+)-flunoxaprofen serum levels following the administration of a single oral dose of flunoxaprofen reach about the same values (between 24 and 30 micrograms/ml at 18 h) whichever form was dosed (i.e. 10 mg/kg b.w. of S(+)- or R(+)-, or 5 mg/kg b.w. of S(+)- as the racemate). On the contrary, R(-)-flunoxaprofen serum concentrations fall to values lower than 5 micrograms/ml either after the administration of 10 mg/kg R(-)- or of 5 mg/kg R(-)- as the racemate; these serum R(-)-flunoxaprofen values are close to those observed after the administration of S(+)-flunoxaprofen which contains 5% R(-)- as an impurity (i.e. 0.5 mg/kg b.w.).(ABSTRACT TRUNCATED AT 250 WORDS)