The utility of endogenous glycochenodeoxycholate-3-sulfate and 4β-hydroxycholesterol to evaluate the hepatic disposition of atorvastatin in rats

The liver is an important organ for drugs disposition, and thus how to accurately evaluate hepatic clearance is essential for proper drug dosing. However, there are many limitations in drug dosage adjustment based on liver function and pharmacogenomic testing. In this study, we evaluated the ability of endogenous glycochenodeoxycholate-3-sulfate (GCDCA-S) and 4β-hydroxycholesterol (4β-HC) plasma levels to evaluate organic anion-transporting polypeptide (Oatps)-mediated hepatic uptake and Cyp3a-meidated metabolism of atorvastatin (ATV) in rats. The concentration of ATV and its metabolites, 2-OH ATV and 4-OH ATV, was markedly increased after a single injection of rifampicin (RIF), an inhibitor of Oatps. Concurrently, plasma GCDCA-S levels were also elevated. After a single injection of the Cyp3a inhibitor ketoconazole (KTZ), plasma ATV concentrations were significantly increased and 2-OH ATV concentrations were decreased, consistent with the metabolism of ATV by Cyp3a. However, plasma 4β-HC was not affected by KTZ treatment despite it being a Cyp3a metabolite of cholesterol. After repeated oral administration of RIF, plasma concentrations of ATV, 2-OH ATV and 4-OH ATV were markedly increased and the hepatic uptake ratio of ATV and GCDCA-S was decreased. KTZ did not affect plasma concentrations of ATV, 2-OH ATV and 4-OH ATV, but significantly decreased the metabolic ratio of total and 4-OH ATV. However, the plasma level and hepatic metabolism of 4β-HC were not changed by KTZ. The inhibition of hepatic uptake of GCDCA-S by RIF was fully reversed after a 7-d washout of RIF. Plasma concentration and hepatic uptake ratio of GCDCA-S were correlated with the plasma level and hepatic uptake of ATV in rats with ANIT-induced liver injury, respectively. These results demonstrate that plasma GCDCA-S is a sensitive probe for the assessment of Oatps-mediated hepatic uptake of ATV. However, Cyp3a-mediated metabolism of ATV was not predicted by plasma 4β-HC levels in rats.     

The utility of endogenous glycochenodeoxycholate-3-sulfate and 4β-hydroxycholesterol to evaluate the hepatic disposition of atorvastatin in rats

The liver is an important organ for drugs disposition, and thus how to accurately evaluate hepatic clearance is essential for proper drug dosing. However, there are many limitations in drug dosage adjustment based on liver function and pharmacogenomic testing. In this study, we evaluated the ability of endogenous glycochenodeoxycholate-3-sulfate (GCDCA-S) and 4β-hydroxycholesterol (4β-HC) plasma levels to evaluate organic anion-transporting polypeptide (Oatps)-mediated hepatic uptake and Cyp3a-meidated metabolism of atorvastatin (ATV) in rats. The concentration of ATV and its metabolites, 2-OH ATV and 4-OH ATV, was markedly increased after a single injection of rifampicin (RIF), an inhibitor of Oatps. Concurrently, plasma GCDCA-S levels were also elevated. After a single injection of the Cyp3a inhibitor ketoconazole (KTZ), plasma ATV concentrations were significantly increased and 2-OH ATV concentrations were decreased, consistent with the metabolism of ATV by Cyp3a. However, plasma 4β-HC was not affected by KTZ treatment despite it being a Cyp3a metabolite of cholesterol. After repeated oral administration of RIF, plasma concentrations of ATV, 2-OH ATV and 4-OH ATV were markedly increased and the hepatic uptake ratio of ATV and GCDCA-S was decreased. KTZ did not affect plasma concentrations of ATV, 2-OH ATV and 4-OH ATV, but significantly decreased the metabolic ratio of total and 4-OH ATV. However, the plasma level and hepatic metabolism of 4β-HC were not changed by KTZ. The inhibition of hepatic uptake of GCDCA-S by RIF was fully reversed after a 7-d washout of RIF. Plasma concentration and hepatic uptake ratio of GCDCA-S were correlated with the plasma level and hepatic uptake of ATV in rats with ANIT-induced liver injury, respectively. These results demonstrate that plasma GCDCA-S is a sensitive probe for the assessment of Oatps-mediated hepatic uptake of ATV. However, Cyp3a-mediated metabolism of ATV was not predicted by plasma 4β-HC levels in rats.     

Dose-dependent pharmacokinetics of a new reversible proton pump inhibitor, DBM-819, after intravenous and oral administration to rats: hepatic first-pass effect.

The dose-dependent pharmacokinetic parameters of DBM-819 were evaluated after intravenous (5, 10 and 20 mg/kg) and oral (10, 20 and 50 mg/kg) administrations of the drug to rats. The hepatic first-pass effect was also measured after intravenous and intraportal administrations of the drug, 10 mg/kg, to rats. After intravenous administration, the dose-normalized (based on 5 mg/kg) area under the plasma concentration-time curve from time zero to time infinity, AUC, at 20 mg/kg (27.0 and 45.8 microg min/ml) was significantly greater than that at 5 mg/kg due to saturable metabolism. After oral administration, the dose-normalized (based on 10 mg/kg) AUC(0-12 h) at 50 mg/kg (25.1, 18.3 and 49.2 microg min/ml) was significantly greater than those at 10 and 20 mg/kg again due to saturable metabolism. After oral administration of DBM-819, 10 mg/kg, 2.86% of oral dose was not absorbed and the extent of absolute oral bioavailability (F) was estimated to be 46.7%. After intraportal administration of DBM-819, 10 mg/kg, the AUC was 51.9% of intravenous administration, suggesting that approximately 48.1% was eliminated by liver (hepatic first-pass effect). The considerable hepatic first-pass effect of DBM-819 was also supported by significantly greater AUC of M3 (3.70 and 6.86 microg min/ml), a metabolite of DBM-819, after intraportal administration. The AUCs of DBM-819 were not significantly different (comparable) between intraportal and oral administrations of the drug, 10 mg/kg, suggesting that gastrointestinal first-pass effect of DBM-819 was almost negligible in rats. At 10 mg/kg oral dose of DBM-819, the hepatic first-pass effect was approximately 48.1%, F was approximately 46.7 and 2.86% was not absorbed from gastrointestinal tract in rats.     

Gastrointestinal and hepatic first-pass metabolism of aspirin in rats

The first-pass effect of aspirin was measured in male Wistar rats by comparing the plasma concentration after intravenous, oral or intraportal administration (10 mg kg-1) of the drug. Approximately 88 and 86% of the dose was excreted mostly as salicylic acid and its conjugated forms, glucuronide and sulphate, in urine within 48 h of i.v. or oral administration, respectively. This suggests that the gastrointestinal absorption of aspirin was essentially complete in rats. On the average, the area under the plasma concentration-time curve for unchanged aspirin following oral dosing (AUCo) was 0.35 of that obtained following i.v. administration (AUCi.v.) and 0.53 of that following intraportal administration (AUCp). Therefore, orally administered aspirin is subject to first-pass metabolism both in the gut and in the liver of rats. The gastrointestinal first-pass effect is estimated to be relatively more important than the hepatic effect.     

Pharmacokinetics and tissue distribution of ketanserin in rat, rabbit and dog

The plasma kinetics and tissue distribution of ketanserin [+)-3-[2-[4-(4-fluorobenzoyl)-1-piperidinyl]ethyl]-2,4(1H,3H)- quinazolinedione, R 41 468) were studied in the rat, rabbit and dog. The studies were performed utilizing 3H- and 14C-labelled ketanserin and appropriate techniques to measure levels of radioactivity, unchanged drug and a major metabolite ketanserin-ol in plasma and tissues. Following intravenous administration to male rats and dogs (10 mg/kg), plasma levels could be described by a two-compartment model. The plasma clearance (C1) averaged 3.8 and 19.2 ml/min/kg and the volume of distribution (Vdss) 0.67 and 4.7 l/kg in male rats and in dogs, respectively. Following oral administration (10-40 mg/kg), ketanserin was rapidly and completely absorbed in all species studied. The absolute bioavailability of oral ketanserin was more than 80% in both rats and dogs. Due to the high clearance of the metabolites in rats, ketanserin was the main component of the plasma radioactivity. In dogs, the fraction of the metabolite ketanserin-ol was more pronounced than that of ketanserin. The apparent elimination half-life of ketanserin was 1.5 h in rabbits, 2-5 h in rats and 3-15 in dogs. The pharmacokinetics of ketanserin were dose-related after single and chronic intravenous and oral dosing. Distribution studies in rats after intravenous and oral administration (10 mg/kg) demonstrated an almost immediate equilibrium between plasma and tissues, resulting in slightly higher tissue than plasma concentrations in the well perfused tissues, and similar or slightly lower levels in the remaining tissues. Ketanserin was the main component of tissue radioactivity. The drug crossed the blood-brain barrier only to a slight extent, brain levels of the unchanged drug being similar to the free fraction in plasma. Ketanserin disappeared from tissues with a similar half-life to that in plasma. On repeated dosing, a small fraction of metabolites was more slowly eliminated. The excretion of the urinary and faecal metabolites after repeated dosing was very similar to that after a single dose. Placental transfer of ketanserin in the rat was limited. On average 0.3% of the maternal radioactive dose, preferentially metabolites, was recovered from the combined foetuses. In dogs orally treated with doses of up to 40 mg/kg/d for 12 months, no undue accumulation or retention of ketanserin or ketanserin-ol was found in any tissue. In lactating dogs orally dosed at 10 mg/kg, preferentially metabolites were excreted in the milk. Concentrations of ketanserin and ketanserin-ol in the milk were respectively 2 and 4 times higher than plasma levels.     

Variability of oral bioavailability for low dose methotrexate in rats.

The effects of food, antibiotics, diclofenac sodium (DS) and methotrexate (MTX) on oral bioavailability (BA) of MTX were examined in rats. Feeding didn't vary the plasma concentrations after intravenous dosing of 0.5 mg/kg MTX, but enhanced those after oral dosing, and the oral BA. The twice daily oral doses of 40 mg/kg neomycin sulfate (NS) or mixed antibiotics (200 mg/kg NS + 200 mg/kg streptomycin sulfate + 200 mg/kg bacitracin) for 5 days didn't influence the plasma concentrations after intravenous dosing of 0.5 mg/kg MTX, but induced the decreased Cmax and the delayed MRT after oral dosing. The plasma concentrations after intravenous or oral dosing of 2.5 mg/kg MTX in rats orally dosed with 1 or 5 mg/kg/day DS for 4 days were similar to those in the control rats, while the pre-treatment of 25 mg/kg/day DS delayed the elimination of MTX but didn't change the oral BA. The plasma concentrations after intravenous or oral dosing of 2.5 mg/kg MTX in rats, which received the intermittent oral doses of 7.5 mg/kg/3 doses/week MTX for 4 weeks, were comparable to those in the control rats, but the daily pre-treatment of 0.2 mg/kg/day MTX for 4 weeks increased the plasma concentrations after oral dosing, and the BA.     

Assessment of the hepatic and intestinal first-pass metabolism of midazolam in a CYP3A drug-drug interaction model rats

In the current study, to understand the characteristics of dexamethasone (DEX)-treated female rats as an animal model for drug-drug interactions, a double-cannulation method was applied and separately assessed for the intestinal and hepatic first-pass metabolism of midazolam. Midazolam was administered intravenously or orally to the animals, and midazolam concentrations in the portal and systemic plasma were simultaneously determined. Next, the rates of elimination from the intestine and liver were estimated using the AUC values. After oral administration of midazolam, the entire drug was absorbed without intestinal first-pass metabolism, and 93% of the administered midazolam was extracted in the liver of the DEX-treated female rats. Seven per cent of the midazolam administered reached the systemic circulation. When ketoconazole was given orally to the animals, in conjunction with midazolam, the extraction ratio in the liver decreased from 93% to 77% in the control rats, and the bioavailability of midazolam increased to 23%. On the other hand, after intravenous administration, the elimination half-life of midazolam was not changed by ketoconazole pretreatment. These results indicated that midazolam is only extracted in the liver of DEX-treated female rats and that ketoconazole inhibits the hepatic first-pass metabolism, but not the systemic metabolism. In conclusion, DEX-treated female rats can be used as a drug-drug interaction model via CYP3A4 enzyme inhibition, especially for the hepatic first-pass metabolism of orally administered drugs.     

Pharmacokinetic drug interactions between ampiroxicam and sulfaphenazole in rats

The aim of the present study was to determine the effect of sulfaphenazole (SP) on the pharmacokinetics of ampiroxicam (AM) which is metabolized by cytochrome P-450 (CYP) 2C9, since SP is a potent inhibitor of CYP 2C9, and so a dramatic pharmacokinetic drug interaction between both drugs is assumed after dosing. Single intravenous and oral administrations of AM (5 and 7.5 mg/kg piroxicam equivalent, respectively) and SP (80 and 120 mg/kg, respectively) to rats did not significantly alter the elimination kinetics of AM and piroxicam (PX) converted from AM. When SP was preloaded orally at 2 h before the dosing of AM, and when AM and SP were orally coadministered for 7 d, the elimination of PX from plasma was slightly retarded and the area under the plasma concentration-time curve (AUC) was increased 77 and 53%, respectively, but not significantly, compared with those after AM alone. On the other hand, a significantly decreased metabolic conversion of PX to 5'-hydroxyPX in plasma was observed by these treatments (p<0.05). In order to clarify the mechanism for the interaction, hepatic and intestinal metabolizing enzyme activities, CYP, uridine 5'-diphosphoglucuronyltransferase (UDPGT) and aryl esterase, were assayed after single and multiple oral administrations of AM or AM and SP. The enzyme activities were hardly inhibited by the treatment, indicating that the inhibition of CYP and hydrolytic enzymes by SP was approximately denied. These results suggest that SP does not significantly affect the pharmacokinetics of AM and PX in rats. However, the pharmacokinetic drug interaction between both drugs in man may not always be ignored.     

Pharmacokinetics of the time-dependent elimination of all-trans-retinoic acid in rats

The time-dependent elimination kinetics of all-transretinoic acid (ATRA) has been associated with autoinduction of its metabolism and has led to the hypothesis that rapid development of acquired clinical resistance to ATRA may be prevented by coadministration of metabolic inhibitors. This study in rats was performed to investigate the pharmacokinetics and onset of time-dependent elimination of ATRA, with the purpose of establishing an animal model suitable for in vivo preclinical studies of compounds capable of inhibiting ATRA metabolism. After the intravenous (IV) bolus administration of single doses of ATRA (1.60 mg kg(-1) and 0.40 mg kg(-1)), the plasma concentration-time curves showed an accelerated decline at 180 minutes after dosing. The plasma clearance (Cl) of ATRA, determined after IV administration of a second dose (1.60 mg kg(-1)), at 180 minutes was greater than Cl after a single dose, thus indicating the existence of a time-dependent elimination process detectable 180 minutes after administration of the first dose. Such time-dependent elimination was confirmed by means of an IV constant-rate infusion of 0.48 mg h(-1) kg(-1) of ATRA during 10 hours. Peak plasma ATRA concentration was achieved at 180 minutes, after which the plasma concentration decreased to reach a much lower apparent steady-state drug concentration at 420 minutes. The area under the plasma concentration-time curve (AUC) obtained after oral administration of a second ATRA dose (1.60 mg kg(-1)) was approximately 8% of the AUC obtained after a single oral dose; consistent with a time-dependent increase in the elimination of ATRA, as was observed after IV administration.     

Absolute bioavailability of [14C] genistein in the rat; plasma pharmacokinetics of parent compound, genistein glucuronide and total radioactivity.

The systemic plasma pharmacokinetics of genistein were determined in rats to evaluate the absolute oral bioavailability and make comparison with similar data in the literature derived from humans subjects. The plasma concentrations of genistein, genistein glucuronide and carbon-14 were determined by LC-MS/MS and liquid scintillation counting following oral and intravenous dosing with [14C]genistein (4 mg kg(-1) body weight). The absorption of total radioactivity from the gut, (parent compound and metabolites), was 56 and 111% in male and female rats, respectively. In contrast, the absolute oral bioavailability of genistein in male and female rats was 7 and 15%. There was a significant (P<0.001) difference between Cmax of genistein after intravenous (6921 and 4392 ng/ml) and oral (21 and 22 ng/ml) dosing in male and female rats, respectively. After oral administration, the concentration profile of genistein glucuronide in plasma greatly exceeded that of parent compound during the absorption/distribution phase suggesting extensive first pass metabolism, and provided evidence of entero-hepatic circulation. Selective plasma analysis by LC-MS/MS, without prior enzymatic hydrolysis, enabled ready discrimination between parent and conjugated metabolites and prevented gross overestimation of genistein bioavailability. Pharmacokinetic parameters Cmax, Tmax and AUC were similar to those reported in humans, which supports the use of the rat model for genistein toxicity studies.     

Increased hepatic nicotine elimination after phenobarbital induction in the conscious rat

Elimination parameters of [14C]nicotine in conscious rats receiving nicotine (0.3 mg/kg) either intravenously or orally were studied. The oral availability of unchanged nicotine, derived by comparison of the respective areas under the concentration vs time curves (AUC), was 89%, indicating low hepatic extraction ratios of about 10%. Pretreatment of rats with phenobarbital (PB) markedly increased hepatic first-pass extraction of nicotine. The oral availability of unchanged nicotine in plasma dropped to 1.4% of the corresponding values obtained from PB-treated rats receiving nicotine iv. After PB pretreatment, the clearance of iv nicotine was increased approximately twofold over controls, much less than the observed more than ninefold increase of hepatic first-pass extraction. It is assumed that extrahepatic metabolism contributed significantly to the rapid removal of nicotine from the plasma. The elimination of cotinine, originating from nicotine administered either po or iv, was significantly increased by PB pretreatment, as determined by the ratio of corresponding AUCs. The pattern of nicotine metabolites in urine also indicated an increase in the rate of cotinine metabolic turnover. The amount of norcotinine in the organic extract of urine paralleled PB microsomal enzyme induction. The ratio between urinary concentrations of the normetabolite and cotinine correlated strongly with the PB-induced state of rat liver. This may be a suitable indicator of PB-inducible hepatic cytochrome P450 isoenzyme(s). Since smoking habits in man are feedback-regulated by nicotine plasma concentrations, a similar increase of nicotine elimination by microsomal enzyme induction in man may be of relevance for tobacco consumption.     

Chronic quercetin feeding decreases plasma concentrations of salicylamide phase II metabolites in pigs following oral administration

We investigated acute effects and effects after chronic intake of the orally administered flavonol quercetin on pharmacokinetics of salicylamide metabolites (SAM) after oral administration of salicylamide in pigs. Salicylamide (8 mg/kg body weight) was orally administered to seven pigs either without or with quercetin (10 mg/kg body weight). Additionally, salicylamide was administered to five pigs that had received a diet supplemented with the flavonol for 1 week. Daily quercetin intake was 10 mg/kg in these animals. Co-ingestion of quercetin with the drug did not alter area under the concentration-time curve (AUC(0→∞)), time to achieve maximum plasma concentration (t(max)), mean residence time (MRT) or half-life (t(1/2)) of SAM. However, maximum plasma concentration (c(max)) of SAM was lower when quercetin was administered concomitantly. After quercetin pre-treatment for 1 week AUC(0→∞), t(1/2) and MRT of SAM were decreased, while other parameters investigated were not affected. Co-ingestions and dietary pre-treatment with quercetin influenced SAM metabolism after oral salicylamide intake. But effects seen after acute concomitant intake are rather explained by induced salicylamide excretion from the intestinal mucosa, whereas quercetin pre-treatment seemed to induce hepatic enzymes involved in phase-II metabolism and thereby enhanced elimination of SAM.     

Pharmacokinetics of l-propranolol during repetitive dosing in normal and uranyl nitrate-induced renal failure rats

The effect of experimental renal failure on the intravenous and oral pharmacokinetics of l-propranolol was studied in rats. Renal failure was induced by a single intravenous injection of uranyl nitrate (5 mg/kg). Pharmacokinetic studies were carried out on the fifth day after injection of the renal toxin (renal failure group) or saline (control group). Serum concentration time course of l-propranolol was characterized after a single intravenous or oral dose as well as after five consecutive doses of the drug given at 3-hr intervals. During repetitive intravenous drug administration, steady state was reached by the second dose, i.e., within 6 hr after initiation of repetitive dosing. No significant difference in the serum concentration time course of l-propranolol was observed between control and renal failure animals. In both groups the AUC over the steady-state dosing interval was on the average 21-27% higher than the AUC after a single dose, indicating a slight decrease in the systemic clearance of l-propranolol during repetitive intravenous drug administration. An approximately two- to three-fold higher serum l-propranolol concentration was observed in renal failure animals as compared to the normal controls after both single or repetitive oral dosing. The apparent reduction in oral clearance probably reflected an inhibition of the hepatic first-pass metabolism of l-propranolol in the renal failure rat. An unexpectedly high and protracted accumulation of serum l-propranolol concentration was observed during repetitive oral drug administration. Continuing accumulation was still evident after the fifth oral dose, i.e., a period of 15 hr or approximately 10 half-lives. The mean AUC over the last dosing interval was 32.0 and 17.8 times higher than the predicted steady-state estimate based on single oral dose data for control and renal failure rats, respectively. The substantial reduction in the oral clearance during repetitive drug administration may be due to an auto-inhibition of l-propranolol metabolism.     

Dose-independent pharmacokinetics of ondansetron in rats: contribution of hepatic and intestinal first-pass effects to low bioavailability

The pharmacokinetic parameters of ondansetron were evaluated after its intravenous (at doses of 1, 4, 8 and 20 mg/kg) and oral (4, 8 and 20 mg/kg) administration to rats. The gastric, intestinal and hepatic first-pass effects of ondansetron were also evaluated after its intravenous, oral, intraportal, intragastric and intraduodenal administration at a dose of 8 mg/kg to rats. After intravenous and oral administration of ondansetron, the drug exhibits dose-independent pharmacokinetics in rats. After oral administration of ondansetron at a dose of 8 mg/kg, the unabsorbed fraction was 0.0158 of the dose, the extent of absolute oral bioavailability (F) value was 0.0407, and the hepatic and intestinal first-pass effects were 40.0% and 34.2% of the oral dose, respectively. The low F of ondansetron in rats was mainly due to considerable hepatic and intestinal first-pass effects. The lower F of ondansetron in rats (4.07%) than that in humans (62+/-15%) was mainly due to greater hepatic metabolism of the drug in rats. Ondansetron was stable in the rat gastric juices and various buffer solutions having pHs ranging from 1 to 13. The equilibrium plasma-to-blood cells partition ratio of ondansetron was 1.74-5.31. Protein binding of ondansetron to fresh rat plasma was 53.2%.     

Pharmacokinetics of sildenafil after intravenous and oral administration in rats: hepatic and intestinal first-pass effects

Pharmacokinetics of sildenafil after intravenous and oral administration at various doses and first-pass effect at 30 mg/kg were evaluated in rats. After intravenous administration (10, 30, and 50 mg/kg), the dose-normalized AUC values were proportional to intravenous doses studied. However, after oral administration (10, 30, and 100 mg/kg), the dose-normalized AUC values increased significantly with increasing doses, possibly due to saturation of metabolism of sildenafil in rat intestinal tract. After oral administration (30 mg/kg), approximately 0.626% was not absorbed and F was 14.6%. The AUC after intragastric administration was significantly smaller (71.4% decrease) than that after intraportal administration, however, the values were not significantly different between intragastric and intraduodenal administration. The above data suggested that intestinal first-pass effect of sildenafil was approximately 71% of oral dose in rats. The AUC values after intraportal administration were significantly smaller (49% decrease) than that after intravenous administration. This suggested that hepatic first-pass effect of sildenafil after absorption into the portal vein was approximately 49% of oral dose in rats (approximately 49% was equivalent to approximately 13.7% of oral dose). The low F of sildenafil at a dose of 30 mg/kg in rats could be mainly due to considerable intestinal first-pass effect.     

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   

Pharmacokinetics, metabolism and excretion of megazol, a new potent trypanocidal drug in animals.

The pharmacokinetics of megazol (CAS 19622-55-0) was investigated after intraperitoneal and oral administration of the drug (80 mg/kg) to mice. The plasma levels were significantly higher after oral administration of drug than after intraperitoneal route (33.8 micrograms/ml compared with 19.0 micrograms/ml for Cmax, 158714 micrograms.h/l compared with 96057 micrograms.h/l for AUC). When suramin (CAS 145-63-1) was administered 24 h before oral administration of megazol, megazol absorption was accelerated (2 h compared with 4 h for Tmax) but the amount absorbed was lower (19.9 micrograms/ml compared with 33.8 micrograms/ml for Cmax and 95547 micrograms.h/l vs 158714 micrograms.h/l for AUC). In the infected mice previously treated with suramin, all estimated pharmacokinetic parameters of plasma megazol were significantly modified, in particularly an increase in the apparent volume of distribution (5.6 l/kg compared with 0.9 l/kg) with a prolongation of the elimination half-life (3 h compared with 0.7 h) of megazol. Excretion of the total radioactivity of megazol was also evaluated after oral administration of 3H-megazol to rats. Total radioactivity was eliminated predominantly via the urinary route (80%) vs. 10.5% in the faeces, 9.5% remaining in the body 8 days after dosing. When unlabelled megazol was orally administered to rats with absence or presence of suramin, megazol recovered in urine and faeces 72 h dosing was: 55.7%/2% vs 20.6%/1.6%, respectively. In the urine, unchanged megazol was present as characterized by LC-MS/MS as well as 4 unknown metabolites. This study indicates that suramin significantly affects the pharmacokinetics of megazol and its elimination.     

Decreased exposure of atorvastatin in diabetic rats partly due to induction of hepatic Cyp3a and Oatp2

1. Atorvastatin is frequently prescribed for lowering blood cholesterol and for prevention of events associated with cardiovascular disease. The aim of this study was to investigate the pharmacokinetics of atorvastatin in diabetic rats.

2. Diabetes was induced in rats by combination of high-fat diet and low-dose streptozotocin (35?mg/kg). Plasma concentrations of atorvastatin following oral (10?mg/kg) and intravenous (2?mg/kg) administrations to rats were measured by LC-MS. Metabolism and uptake of atorvastatin in primary hepatocytes of experimental rats were assessed. Protein expressions and activities of hepatic Cyp3a and Oatp2 were further investigated.

3. Clearances of atorvastatin in diabetic rats following oral and intravenous administrations were remarkably increased, leading to marked decreases in area-under-the-plasma concentration–time curve (AUC). The estimated oral and systematic clearances of atorvastatin in diabetic rats were 4.5-fold and 2.0-fold of control rats, respectively. Metabolism and uptake of atorvastatin in primary hepatocytes isolated from diabetic rats were significantly increased, which were consistent with the up-regulated protein expressions and activities of hepatic Cyp3a and Oatp2.

4. All these results demonstrated that the plasma exposure of atorvastatin was significantly decreased in diabetic rats, which was partly due to the up-regulated activities and expressions of both hepatic Cyp3a and Oatp2.     

Effects of morin on the pharmacokinetics of docetaxel in rats with 7,12-dimethylbenz[a]anthracene (DMBA)-induced mammary tumors

Docetaxel is a P-glycoprotein (P-gp) substrate and metabolized via cytochrome P450 (CYP) 3A subfamily in rats. Morin is an inhibitor of both CYPs and P-gp. Hence, the effects of morin on the intravenous and oral pharmacokinetics of docetaxel were investigated using 7,12-dimethylbenz[a]anthracene (DMBA)-induced mammary tumor rats (DMBA rats) as an animal model of human breast cancer. Docetaxel was administered intravenously (4 mg/kg) and orally (20 mg/kg) without and with morin (15 mg/kg) in DMBA rats. After the intravenous administration of docetaxel in control and DMBA rats with and without morin, the values of non-renal clearance and area under the plasma concentration-time (AUC) for docetaxel were comparable. Morin did not increase AUC or the absolute oral bioavailability (F) for docetaxel after the oral administration of docetaxel in control and DMBA rats with and without morin. The inhibition of hepatic and intestinal metabolism of docetaxel by morin and/or DMBA and the effect of intestinal P-gp inhibition by morin on the pharmacokinetics of docetaxel did not seem to be considerable in DMBA-induced mammary tumor rats.     

Pharmacokinetics and metabolism of tomoxiprole, a new analgesic antiinflammatory agent, in the rat

The pharmacokinetics and the metabolic profile of tomoxiprole, a new analgesic antiinflammatory agent belonging to the class of 3-alkyl-2-aryl-3H-naphth (1,2-d)imidazoles, were studied in the rat. After oral administration (5 mg/kg) to male rats, tomoxiprole was rapidly absorbed, mostly by the gut, and reached maximum plasma levels of about 0.5 microgram/ml in 0.25-2 h. A metabolic first pass reduced the extent of oral bioavailability of the parent compound to about half, while absorption (total 14C data) was estimated to be complete. After intravenous injection (2.5 mg/kg), the plasma kinetics of tomoxiprole in male rats showed a bi-exponential profile, and the terminal elimination half-life was 4.2 h. The apparent volume of distribution was high, suggesting a wide distribution of the drug. Increasing the oral dose by ten times (50 mg/kg), resulted in linear kinetics with a proportional increase of the C max and AUC values and the same value of terminal elimination half-life. In females given a 5 mg/kg dose, the plasma levels of 14C, tomoxiprole and AUC values were somewhat higher than in males. The plasma levels of total 14C after iv or po treatments were higher and more sustained than those of tomoxiprole. The kinetic profile after iv administration was described by a three exponential terms equation and the terminal elimination half-life was 38.7 h. Upon iv administration, total 14C was rapidly distributed in highly vascularized tissues while in others, like the bone, fat, gonads, pancreas and skin the equilibrium with the central compartment was attained later. Target organs were the adrenals, liver, lungs, pancreas, thyroid, stomach and above all the fat tissue. Elimination from tissues was almost complete 48 h after the treatment. 14C was eliminated mainly in the feces (80% of dose) as metabolites. In the bile, five polar metabolites were detected; one of them, desmethyl tomoxiprole glucuronide, accounting alone for more than 80% of the total biliary radioactivity; was purified and its structure assigned.