Liver and Gastrointestinal First-pass Effects of Azosemide in Rats

Since considerable first-pass effects of azosemide have been reported after oral administration of the drug to rats and man, first-pass effects of azosemide were evaluated after intravenous, intraportal and oral administration, and intraduodenal instillation of the drug, to rats. The total body clearances of azosemide after intravenous (5 mg kg^?) and intraportal (5 and 10 mg kg^?) administration of the drug to rats were considerably smaller than the cardiac output of rats suggesting that the lung or heart first-pass effect (or both) of azosemide after oral administration of the drug to rats was negligible. The total area under the plasma concentration-time curve from time zero to time infinity (AUC) after intraportal administration (5 mg kg^?) of the drug was significantly lower than that after intravenous administration (5 mg kg^?) of the drug (1000 vs 1270 μg min mL^?) suggesting that the liver first-pass effect of azosemide was approximately 20% in rats. The AUC from time 0 to 8 h (AUC_{0–8 h}) after oral administration (5 mg kg^?) of the drug was considerably smaller than that after intraportal administration (5 mg kg^?) of the drug (271 vs 1580 μg min mL^?) suggesting that there are considerable gastrointestinal first-pass effects of azosemide after oral administration of azosemide to rats. Although the AUC_{0–8 h} after oral administration (5 mg kg^?) of azosemide was approximately 15% lower than that after intraduodenal instillation (5 mg kg^?) of the drug (271 vs 320 μg min mL^?), the difference was not significant, suggesting that the gastric first-pass effect of azosemide was not considerable in rats. Azosemide was stable in human gastric juices and pH solutions ranging from 2 to 13. Almost complete absorption of azosemide from whole gastrointestinal tract was observed after oral administration of the drug to rats. The above data indicated that most of the orally administered azosemide disappeared (mainly due to metabolism) following intestinal first-pass in rats.     

Pharmacokinetics of a non-narcotic analgesic,DA-5018, in rats

The pharmacokinetics of a non-narcotic analgesic, DA-5018, were compared after single intravenous (IV), subcutaneous (SC), and oral administrations, and after multiple (seven consecutive days) SC administration to rats. After IV administration of DA-5018, 1, 2, and 5 mg kg⁻¹, the pharmacokinetic parameters of DA-5018 were independent of the dose ranges studied. After oral administration of DA-5018, absorption of the drug from gastrointestinal (GI) tract was fast, but the extent of absolute bioavailability (F) was low; the values were 23.2, 23.0, and 27.3% for 2, 5, and 10 mg kg⁻¹, respectively. After single SC administration of DA-5018, absorption of the drug from the injected site was fast and the extent of absorption was fairly good; the F values were 74.5 and 71.8% for 2 and 5 mg kg⁻¹, respectively. The lower F values after oral administration of DA-5018 to rats could be due to degradation of the drug in rat GI tract and/or considerable first-pass effect. After IV, oral, and SC administration of DA-5018, the drug had a strong affinity to the rat tissues studied as reflected in the greater-than-unity tissue to plasma ratio. After IV, oral, and SC administration of the drug, the biliary and urinary excretion of unchanged DA-5018 were negligible. There was no significant difference in the pharmacokinetics or tissue distribution of DA-5018 between single and multiple SC administration of the drug, 5 mg kg⁻¹, to rats, indicating that there could be no tissue accumulation of the drug after multiple SC administration of the drug to rats. © 1998 John Wiley & Sons, Ltd.     

Pharmacokinetics of deramciclane in dogs after single oral and intravenous dosing and multiple oral dosing

The pharmacokinetics of a new serotonin 5-HT₂ antagonist, deramciclane, was studied. Single oral doses of 1, 3, 6 and 10 mg kg⁻¹ and intravenous doses of 1, 3 and 6 mg kg⁻¹ were administered in beagle dogs. Moreover, the steady state pharmacokinetics of 1, 3 and 6 mg kg⁻¹ doses were studied. Deramciclane was rapidly and completely absorbed from the gastrointestinal tract. Due to a moderate first-pass metabolism the absolute bioavailability was only 45–61%. Deramciclane had a large volume of distribution (32–37 L kg⁻¹) because of its lipophilic nature. Deramciclane was extensively metabolized after intravenous injection and only trace amounts of intact drug is excreted in the urine. The total body clearance decreased (from 32 to 17 L h⁻¹) as the dose increased. It is suggested that the metabolic capacity was not sufficient to eliminate deramciclane in a linear manner with increasing dose. Therefore, deramciclane exhibited nonlinear pharmacokinetics as the AUC_0–∞ increased disproportionally to the dose after both intravenous and oral dosing. Formation of the active metabolite, N-desmethyl deramciclane, was also nonlinear (p =0.0002). At steady state deramciclane accumulated less than 2-fold during repeated administration. Copyright © 1998 John Wiley & Sons, Ltd.     

Pharmacokinetics and tissue distribution of a new carbapenem,DA-1131, after intravenous administration to mice,rats, rabbits and dogs

The pharmacokinetic parameters including tissue distribution and/or biliary excretion of DA-1131, a new carbapenem, were evaluated after intravenous (iv) administration to mice, rats, rabbits, and dogs. After iv administration to mice (20, 50, 100, and 200 mg kg⁻¹), rats (50, 100, 200, and 500 mg kg⁻¹), rabbits (20, 50, 100, and 200 mg kg⁻¹), and dogs (10, 20, 50, 100, and 200 mg kg⁻¹), the pharmacokinetic parameters of DA-1131 seemed to be independent of DA-1131 doses studied in all four animal species. However, the renal clearance and percentage of iv dose of DA-1131 excreted in 24 h urine as unchanged drug decreased significantly in rabbits (from 200 mg kg⁻¹) and dogs (from 100 mg kg⁻¹) due to reduced kidney function induced by DA-1131. The creatinine clearance decreased significantly in rabbits at 200 mg kg⁻¹ compared with that in the control rabbits (0.466 versus 4.31 mL min⁻¹ kg⁻¹). Renal active secretion of DA-1131 was observed in rabbits and was less considerable in rats, but renal active reabsorption of DA-1131 was observed in dogs. Although DA-1131 was widely distributed in all tissues studied in mice (20–200 mg kg⁻¹), rats (200 mg kg⁻¹), rabbits (50 mg kg⁻¹), and dogs (50 mg kg⁻¹), affinity of DA-1131 for tissues was low: the tissue-to-plasma concentration ratios were greater than unity only in the kidney and/or liver. The low affinity of DA-1131 for tissues was also supported by relatively low values of the apparent volume of distribution at steady state in rats (147–187 mL kg⁻¹), rabbits (91.7–148 mL kg⁻¹), and dogs (243–298 mL kg⁻¹). The contribution of biliary excretion of unchanged DA-1131 to nonrenal clearance of DA-1131 seemed to be minor in rats (200 mg kg⁻¹) and dogs (50 mg kg⁻¹); the percentages of iv dose excreted in 8 h bile as unchanged DA-1131 were 1.76 and 2.71% after iv administration of the drug to rats and dogs, respectively. © 1998 John Wiley & Sons, Ltd.     

Pharmacokinetics and urinary excretion of DMXBA (GTS-21), a compound enhancing cognition

DMXBA (3-(2, 4-dimethoxybenzylidene)-anabaseine, also known as GTS-21) is currently being tested as a possible pharmacological treatment of cognitive dysfunction in Alzheimer's disease. In this study, plasma and brain pharmacokinetics as well as urinary excretion of this compound have been evaluated in adult rats. DMXBA concentrations were determined by HPLC. Following a 5 mg kg⁻¹ iv dose, DMXBA plasma concentration declined bi-exponentially with mean (±SE) absorption and elimination half-lives of 0.71±0.28 and 3.71±1.12 h, respectively. The apparent steady state volume of distribution was 2150±433 mL kg⁻¹, total body clearance was 1480±273 mL h⁻¹ kg⁻¹, and AUC_0–∞ was 3790±630 ng h mL⁻¹. Orally administered DMXBA was rapidly absorbed. After oral administration of 10 mg kg⁻¹, a peak plasma concentration of 1010±212 ng mL⁻¹ was observed at 10 min after dosing. Elimination half-life was 1.740±0.34 h, and AUC_0–∞ was 1440±358 ng h mL⁻¹. DMXBA peak brain concentration after oral administration was 664±103 ng g⁻¹ tissue, with an essentially constant brain–plasma concentration ratio of 2.61±0.34, which indicates that the drug readily passes across the blood–brain barrier. Serum protein binding was 80.3±1.1%. Apparent oral bioavailability was 19%. Renal clearance (21.8 mL h⁻¹ kg⁻¹) was less than 2% of the total clearance (1480±273 mL h⁻¹ kg⁻¹); urinary excretion of unchanged DMXBA over a 96 h period accounted for only 0.28±0.03% of the total orally administered dose. Our data indicates that DMXBA oral bioavailability is primarily limited by hepatic metabolism. © 1998 John Wiley & Sons, Ltd.     

EXTRAHEPATIC FIRST-PASS METABOLISM OF NIFEDIPINE IN THE RAT

The peroral (po) bioavailability of nifedipine is reported to range from about 45 to 58% in the rat; this compares favourably to human beings. The metabolism of nifedipine is similar in rats and humans (oxidation of the dihydropyridine ring), with the liver believed to be solely responsible for the systemic clearance of the drug and the observed first-pass effect after po dosing. The purpose of this study was to determine whether intestinal metabolism also contributes to the first-pass elimination of nifedipine in the rat. The systemic availabilities of nifedipine doses given by po, intracolonic (ic), and intraperitoneal (ip) routes of administration were compared to that for an intravenous (iv) dose (in each case a dose of 6 mg kg⁻¹ was given) using adult male Sprague–Dawley rats (249–311 g, n =6 or 7/group). The geometric mean of systemic nifedipine plasma clearance after iv dosing was 10·3 mL min⁻¹ kg⁻¹. The nifedipine blood-to-plasma ratio was found to be about 0·59. Therefore, the systemic blood clearance of nifedipine was about 17·5 mL min⁻¹ kg⁻¹; which, compared to the hepatic blood flow of rats (55 to 80 mL min⁻¹ kg⁻¹) showed that nifedipine is poorly extracted by the liver (0·22≤E_H≤0·32). The mean absolute bioavailabilities of the po, ip, and ic doses were 61, 90, and 100%, respectively. Assuming complete absorption of the extravascular nifedipine doses these results indicate that, in addition to hepatic extraction, substantial first-pass elimination of nifedipine occurs within the wall of the small intestine but not the colon of the rat. © 1997 John Wiley & Sons, Ltd.     

Pharmacokinetics of single oral and multiple intravenous and oral administration of acebutolol enantiomers in a rat model

Acebutolol (AC), is a chiral, β -adrenergic blocking agent which possesses partial agonist activity and is metabolized to an equipotent chiral metabolite, diacetolol (DC). The enantiomeric disposition of AC is reported following racemic administration as a single oral (p.o., 50 mg kg⁻¹) or as a multiple thrice daily intravenous (i.v.) or p.o. dosing for four days in male Sprague–Dawley rats (n =6). Enantiomeric concentrations of AC and DC in plasma and urine were determined using a stereospecific HPLC assay. The bioavailabilities of R- and S-enantiomer were 0.40 and 0.39 after single dose administration of AC respectively. These values were increased to 0.51 and 0.53 after multiple dosing. Although no significant differences were found in AUC_0–∞ after single i.v. as compared with AUC_0–τ after multiple i.v. dosing of AC, the 39 and 45% increase in mean AUC_0–τ were found after multiple p.o. dosing over the corresponding AUC_0–∞, for the single p.o. dose of AC for R- and S-enantiomer, respectively. The disposition of DC as well as the urinary excretion of metabolite was stereoselective in favor of R-enantiomer after oral administration of AC. These results indicate that AC enantiomers have low availability and moderate extraction through the first-pass metabolism in a rat model. The higher AUC values after p.o. multiple dosing may suggest a saturable first-pass metabolism of AC. © 1998 John Wiley & Sons, Ltd.     

Pharmacokinetic and pharmacodynamic changes of azosemide after intravenous and oral administration of azosemide to uranyl nitrate-induced acute renal failure rats

The pharmacokinetic and pharmacodynamic differences of azosemide were investigated after intravenous (IV) and oral administration of azosemide, 10 mg kg⁻¹, to the control and uranyl nitrate-induced acute renal failure (U-ARF) rats. After IV administration, the plasma concentrations of azosemide were significantly higher in the U-ARF rats and this resulted in a significant increase in AUC (2520 versus 3680 μg min mL⁻¹) and significant decrease in Cl (3.96 versus 2.72 mL min⁻¹ kg⁻¹) of azosemide. The significant decrease in Cl in the U-ARF rats was due to the significant decrease in Cl_r of azosemide (1.55 versus 0.00913 mL min⁻¹ kg⁻¹) due to the decrease in kidney function in the U-ARF rats. After IV administration, the urine output (38.5 versus 8.45 mL 100 g⁻¹ body weight) and urinary excretion of sodium (4.60 versus 0.420 mmol 100 g⁻¹ body weight) decreased significantly in the U-ARF rats. After oral administration, the AUC_{0–8 h} of azosemide decreased significantly (215 versus 135 μg min mL⁻¹) in the U-ARF rats possibly due to the decreased GI absorption of azosemide. After oral administration, the 24-h urine output decreased considerably (16.1 versus 11.2 mL 100 g⁻¹ body weight, p <0.098) and the 24-h urinary excretion of sodium (1.74 versus 0.777 mmol 100 g⁻¹ body weight) decreased significantly in the U-ARF rats. The IV and oral doses of azosemide needed to be modified in the acute renal failure patients if the present rat data could be extrapolated to humans. © 1998 John Wiley & Sons, Ltd.     

Influence of cholestyramine on the pharmacokinetics of rosiglitazone and its metabolite,desmethylrosiglitazone, after oral and intravenous dosing of rosiglitazone: Impact on oral bioavailability,absorption, and metabolic disposition in rats

The possible influence of the bile acid-sequestering agent cholestyramine (CSA), which is a basic co-medication in hypercholesterolemic patients, on the pharmacokinetics of rosiglitazone (RGL) and its circulating metabolite desmethylrosiglitazone (DMRGL) was investigated following a single oral and intravenous dose of RGL to Wistar rats. The pharmacokinetic parameters of RGL and DMRGL were evaluated following oral or intravenous administration of RGL to rats at 10?mg?kg^?1 with and without pre-treatment (0.5?h before RGL administration) of CSA at 0.057, 0.115, 0.23 and 0.34?g?kg^?1 doses. With an increase in CSA dose there was dose-dependent decrease in area under the curve (AUC)_(0?∞) and C_max with no change in T_max, K_el and t_1/2 values for both RGL and DMRGL following oral administration of RGL. The oral bioavailability of RGL was reduced by 19.9, 35.6, 53.8 and 72.0% in rats following pre-treatment with CSA at 0.057, 0.115, 0.230 and 0.340?g?kg^?1, respectively. There was no change in the above-mentioned pharmacokinetic parameters for RGL and DMRGL in rats when RGL was given intravenously following pre-treatment with the above-mentioned oral doses of CSA. Another objective of the study was to determine the effect of staggered oral CSA dosing at 1, 2 and 4?h after oral RGL administration at 10?mg?kg^?1. AUC_(0?∞) of RGL and DMRGL was reduced following CSA staggered administration at 1?h, whereas 2- and 4-h staggered dose administration of CSA had no effect on the AUC_(0?∞) of RGL and DMRGL. Irrespective of CSA staggered dose administration there was no change in other pharmacokinetic parameters, namely C_max, T_max, K_el and t_1/2. The apparent formation rate constant (K_f) of DMRGL was also calculated to show that only the absorption of RGL was affected, not the apparent formation rate of DMRGL. The authors also studied the in vitro adsorption of RGL (100, 250, 500?µg?ml^?1) at various pH conditions (pH 2, 4 and 7) and different concentrations of CSA (15, 30, 60 and 120?mg?ml^?1). The percentage binding of CSA was in the range 50–72% (at pH 2), 74–89% (at pH 4) and 97–100% (at pH 7). In conclusion, we carried out a systematic investigation demonstrating mechanistically the interaction potential of RGL when co-administered with CSA. The applicability of the metabolite data after intravenous and oral dosing and pH-based binding experiments further adds credence to the key findings.     

Species differences in hydrolase activities toward OT-7100 responsible for different bioavailability in rats,dogs, monkeys and humans

OT-7100 (5-n-butyl-7-(3,4,5-trimethoxybenzoylamino)pyrazolo[1,5-a] pyrimidine) is an amide moiety-bearing pyrazolopyrimidine derivative with a potential analgesic effect. To determine the factors responsible for observed species differences in the bioavailability of this drug, human and experimental animal samples were used to investigate in vitro microsomal and cytosolic hydrolase activities in the liver and small intestine vis-à-vis the pharmacokinetics of OT-7100. The AUC_0–t values of OT-7100 after oral administration in rats, dogs and monkeys were 0.163, 0.0383 and 0.00147?µg?h?ml^?1 divided by mg?kg^?1, respectively. The bioavailabilities of OT-7100 after oral administration in rats, dogs and monkeys were 36, 17 and 0.3%, respectively. The plasma concentration–time profiles of intravenously administrated OT-7100 in rats, dogs and monkeys were similar. The hydrolase activities toward OT-7100 in liver microsomes or cytosol were approximately similar in rats, dogs, monkeys and humans. In contrast, hydrolase activities of small intestinal microsomes from monkeys were higher (36.1?ng?mg?protein^?1?min^?1) than those of rats, dogs and humans (5.4, 1.4 and 4.3?ng?mg?protein^?1?min^?1, respectively). These results suggest that the primary factor influencing first-pass metabolism for the OT-7100 is enzymatic hydrolysis in the small intestine. This information provides an important index for extrapolating the pharmacokinetics of drugs in humans using studies on monkeys.     

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, ¹⁴C-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–∞ of total radioactivity were 36.2 and 47.1?µg?eq.?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.     

PHARMACOKINETICS AND TOXICOKINETICS OF AN ORALLY ACTIVE TRIPEPTIDE,IRI-695, IN ANIMALS

Pharmacokinetics and toxicokinetics of IRI-695, a tripeptide, were investigated in the rat, rabbit, dog, and monkey. Tissue distribution and excretion of [¹⁴C]IRI-695 were determined in the rat. Following a single intravenous (IV) injection, the elimination half-life (t_1/2) of IRI-695 in the rabbit, dog, and monkey was similar (about 65 min) and approximately four times that in the rat (15 min). This difference in t_1/2 can be attributed to about four times higher clearance of the drug in rats (11·2 mL min⁻¹ kg ⁻¹). The volume of distribution (V_ss) in these four species, 132–234 mL kg⁻¹, suggested negligible preferential distribution of IRI-695 to body tissue. After a 5 mg kg⁻¹ oral dose, the absolute bioavailability of IRI-695 was 2·0% in rats and 3·1% in dogs. However, systemic drug exposure in the dog was about five to 10 times that in the rat, which is related to the slower clearance of the peptide in the dog. Toxicokinetic studies in the rat and dog indicated linear kinetics and systemic exposure of IRI-695 up to 300 mg kg⁻¹ d⁻¹ oral doses throughout the 28 d toxicity study. Accumulation of the drug after the repeated oral dosing was negligible. After a single 0·10 mg kg⁻¹ ]¹⁴C[IRI-695 IV injection in rats, almost all of the radioactivity administered was excreted in urine within 24 h postdose.     

Enantioselective Pharmacokinetics of Homochlorcyclizine: Disposition of (+)- and (–)-Homochlorcyclizine after Intravenous and Oral Administration of Racemic Homochlorcyclizine to Rats

Abstract— Concentrations of homochlorcyclizine enantiomers in blood, urine, and tissues of the liver, lung, kidney, brain, heart, spleen, intestine and stomach of rats after drug administration were determined by high-performance liquid chromatography on a chiral stationary phase. After intravenous administration (10 mg kg^?1), homochlorcyclizine was rapidly distributed in many tissues, with the highest concentration in lung. No differences were found between enantiomers in blood concentrations. After oral administration (50 mg kg^?1), the concentrations of the (+)-isomer in nearly all tissues were higher than those of the (–)-isomer. The AUC_0-x values of the (+)- and (–)-isomers differed significantly. The absorption of racemic homochlorcyclizine from rat small intestine was not enantioselective. These results suggested that the different concentrations between enantiomers after oral administration were not caused by enantioselective absorption or distribution but rather by preferential first-pass metabolism of the (–)-isomer in the liver. The enantioselectivity of metabolism was also demonstrated by in-vitro experiments.     

Pharmacokinetics and pharmacodynamics of bumetanide after intravenous and oral administration to spontaneously hypertensive rats and DOCA-salt induced hypertensive rats

The pharmacokinetics and pharmacodynamics of bumetanide were investigated after intravenous (i.v.) administration, 10 mg kg^?1, and oral administration, 20 mg kg^?1, to spontaneously hypertensive rats (SHRs) and deoxycorticosterone acetate-salt induced hypertensive rats (DOCA-salt rats). After i.v. administration, the pharmacokinetic and pharmacodynamic parameters of bumetanide did not vary significantly between SHRs and the control Wistar rats. Similar results were also shown between DOCA-salt rats and the control Sprague-Dawley (SD) rats. After oral administration, the AUC_{0–12 h} decreased significantly (186 versus 335 μg min ml^?1) in SHRs and this resulted in decreased F(15.4 versus 23.6 and 2.78 versus 5.76% using two equations) in SHRs when compared with the control Wistar rats, although none of the other pharmacokinetic parameters varied significantly between SHRs and Wistar rats. This effect seemed to be due to the decreased enterohepatic recirculation of bumetanide in SHRs: the amounts of both bumetanide and its glucuronide product, which are capable of enterohepatic recirculation, excreted in 8 h bile juice decreased significantly in SHRs (11.3 versus 37.4 μg as expressed in terms of bumetanide) when compared with Wistar rats. The pharmacodynamic parameters did not vary significantly between SHRs and Wistar rats after oral administration of bumetanide. The pharmacokinetic and pharmacodynamic parameters of bumetanide did not vary significantly between DOCA-salt rats and SD rats after oral administration of the drug. The liver weights compared to body weight increased significantly in SHRs when compared with Wistar rats and the corresponding values for the kidney increased significantly in DOCA-salt rats when compared with SD rats.     

Pharmacokinetics of lipoyl vildagliptin,a novel dipeptidyl peptidase IV inhibitor after oral administration in rats

1. The pharmacokinetics of lipoyl vildagliptin, a novel dipeptidyl peptidase IV (DPP IV) inhibitor, was studied in rats after oral administration for developing it as an antidiabetic agent.

2. A liquid chromatography-tandem mass spectroscopy (LC-MS/MS) method was developed to determine lipoyl vildagliptin in rat plasma. After an overnight fasting, rats were orally given lipoyl vildagliptin. Following a single oral dose of 25, 50, and 100?mg·kg^?1, T_max values were from 1.25 to 1.84?h, CL/F values were around 100?l h^?1 kg^?1. In the dose range, C_max values (63.9–296?μg·l^?1) and AUC_0–∞values (260–1214?μg·h·l^?1) were proportional to the doses.

3. In conclusion, this LC-MS/MS method for the determination of lipoyl vildagliptin in rat plasma was selective and sensitive. In rats, lipoyl vildagliptin displayed linear pharmacokinetics after a single oral dose in the range of 25–100?mg·kg^?1. Lipoyl vildagliptin might have very high CL/F values and V_d/F values, which indicated that the bioavailability of this drug might be low or lipoyl vildagliptin might distribute extensively or accumulate in tissues in view of its high liposolubility.

     

COMPARISON OF PHARMACOKINETICS OF M1, M2, M3, AND M4 AFTER INTRAVENOUS ADMINISTRATION OF DA-125 OR ME2303 TO MICE AND RATS. NEW ADRIAMYCIN ANALOGUES CONTAINING FLUORINE

The pharmacokinetics of M1, M2, M3, and/or M4 were compared after intravenous (iv) administration of DA-125 and/or ME2303 to mice (25 mg kg⁻¹) and rats (5, 10, 20, 30, and 40 mg kg⁻¹). The mean plasma concentrations of M1 were detected up to 8 h after iv administration of both DA-125 and ME2303 to mice, and were significantly higher for DA-125 than ME2303; this resulted in a considerably greater AUC (303 against 148 μg min mL⁻¹) and a considerably slower CL of M1 (69·3 against 136 mL min⁻¹ kg⁻¹) after iv administration of DA-125. The MRT (371 against 189 min) and CL_NR of M1 (68·7 against 136 mL min⁻¹ kg⁻¹) were considerably greater and slower, respectively, after iv administration of DA-125. The mean plasma concentrations of M2 were detected up to 8 and 4 h after iv administration of DA-125 and ME2303, respectively, to mice and were significantly higher for DA-125 than ME2303, resulting in a considerably greater AUC of M2 (148 against 27·1 μg min mL⁻¹) after iv administration of DA-125. The mean plasma concentrations of M3, being the lowest among M1–M4, were detected only up to 15 min after iv administration of both DA-125 and ME2303 to mice, and were comparable after iv adminstration of DA-125 and ME2303 to mice. The mean plasma concentrations of M4 were detected up to 8 h after iv administration of both DA-125 and ME2303 to mice, and were higher after iv administration of DA-125 than ME2303, resulting in a considerably greater AUC of M4 (197 against 61·9 μg min mL⁻¹) after iv administration of DA-125. Similar results on M1 and M2 were also obtained from rats: the mean plasma concentrations of both M1 and M2 were significantly higher after iv administration of DA-125, 10 mg kg⁻¹, than after ME2303. The plasma concentrations of M1, M2, and M4, and hence their AUCs, were significantly higher after iv administration of DA-125, 5, 10, 20, 30, and 40 mg kg⁻¹, to rats than after ME2303: the mean plasma concentrations of M2, approximately 0·1–0·4 μg mL⁻¹, were maintained from 30 min to 8–10 h after iv administration of DA-125, 20, 30, and 40 mg kg⁻¹, to rats; the plasma concentrations of M3 were the lowest among M1–M4 at all DA-125 doses; and those of M1 and M4 were maintained for a long period of time. However, after iv administration of M2, 5 mg kg⁻¹, to rats, the mean plasma concentrations of M2 were detected up to 60 min with a mean terminal half-life of only 38·8 min, and the concentrations of M3 were negligible. After iv administration of M3, 5 mg kg⁻¹, to rats, the mean plasma concentrations of M3 were detected up to 15 min; the plasma concentrations of M4, reaching their peak at 5 min, decayed more slowly and were higher than those of M3. The AUC of M4 after iv administration of M3, 5 mg kg⁻¹, was comparable to that after iv administration of M4, 5 mg kg⁻¹, to rats, suggesting that M4 is formed fast and almost completely from M3. M1 was not detected in plasma after iv administration of either M2 or M3 to rats. After iv administration of M4, 5 mg kg⁻¹, to rats, the mean plasma concentrations of M4 decayed fast with a mean terminal half-life of 43·9 min and neither M2 nor M3 were detected in plasma. The following disposition mechanisms for M1, M2, M3, and M4 after iv administration of DA-125 to rats could be obtained from the above data: (i) the maintenance of plasma concentrations of M2 for a longer period of time after iv administration of DA-125 than those after iv administration of M2 could be due to the continuous formation of M2 from M1; (ii) the lowest plasma concentrations of M3 among M1–M4 after iv administration of DA-125 could be due to the fast and almost complete formation of M4 from M3 as soon as M3 is formed from M1, and not due to the fast renal excretion of unchanged M3; (iii) M4 was exclusively and continuously formed from M3 and the formation of M4 from M2 was negligible; and (iv) reversible metabolism among M1–M4 did not take place. The following results could also be obtained after iv administration of DA-125 or ME2303 to mice and rats: (i) the lower plasma concentrations of M1 after iv administration of ME2303 than of DA-125 could be due to the greater biliary excretion of unchanged ME2303 (approximately 30% of iv dose) than unchanged DA-125 and (ii) the lower plasma concentrations of M2 and M4 after iv administration of ME2303 than after DA-125 could be due to lower plasma concentrations of M1 and hence less formation of both M2 and M4 from M1. Liver showed the highest metabolic activity for M1 and a considerable amount of M1 was also metabolized in the kidney after 30 min incubation of 50 μg of DA-125 in 9000 g supernatant fraction of rat tissue homogenates. The mean amount of M1 remaining per gram of tissue, the total amount of M1 remaining in whole tissue, and the tissue to plasma ratio of M1 were significantly higher in the heart, lung, large intestine, and kidney at 15 min after iv administration of DA-125, 25 mg kg⁻¹, to mice than after ME2303. M1, the active antineoplastic moiety of DA-125, had higher affinity for the lung after iv administration of DA-125 to mice than after ME2303, indicating that lung tumours could be subjected to a greater exposure to M1 after iv administration of DA-125 than ME2303. The 24 h biliary excretion of M1 was significantly greater after the iv administration of ME2303 than after DA-125 (344 against 79·3 μg). However, reversed results were obtained for M2 (267 against 467 μg). M3 and M4 were under the detection limit in the bile sample after iv administration of either DA-125 or ME2303.     

Pharmacokinetics of SDZ 64-412, a novel antiasthmatic agent,following intravenous,oral, and inhalation dosing in the rat

The pharmacokinetics of SDZ 64–412, an antiasthmatic agent, were investigated following intravenous, oral, and inhalation dosing in rats. ¹⁴C-SDZ 64–412 was administered intravenously (2.75 mg kg^?1) and orally (5.5 mg kg^?1, 110 mg kg^?1), whereas non-radiolabeled drug (5.04 mg kg^?1) was administered using nose-only inhalation chambers. Radioactivity and parent drug concentrations in blood, lung, and excreta were determined at designated times post-dose. SDZ 64–412 was rapidly and extensively (～80%) absorbed following both oral doses, although absorption appeared to be prolonged with increasing dose. The absorbed drug was shown to undergo extensive and saturable first-pass metabolism. The bioavailability of the parent drug, calculated by dose-normalized AUC and deconvolution methods, was only 10–15% from the low dose, but increased to ～40% following the high dose. Following inhalation dosing, SDZ 64–412 concentrations in blood and lungs increased rapidly, and did not decline immediately after termination of dosing. The inhalation dose yielded a bioavailability of ～40%, and AUC of the drug in lungs was approximately 25 times greater than in blood. In general, SDZ 64–412 was extensively distributed and rapidly eliminated from the systemic circulation. Biliary excretion was the predominant route of radioactivity excretion. The present findings suggest that inhalation administration provides a viable means of delivery of SDZ 64–412.     

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.     

Effects of diammonium glycyrrhizinate on the pharmacokinetics of aconitine in rats and the potential mechanism

1. The objective of this study was to investigate the effects of diammonium glycyrrhizinate on the pharmacokinetics of aconitine in rats and the potential mechanism.

2. After oral administration of diammonium glycyrrhizinate (50?mg kg^?1), the peak plasma concentration (C_max), area under the plasma concentration–time curve from zero to time τ (AUC_0–τ), and absolute bioavailability of aconitine (0.2?mg kg^?1) significantly increased 1.64-, 1.63- and 1.85-fold, respectively, but there was no significant change in half life (t_1/2) or clearance (CL). In the other two routes of administration via the tail vein and hepatic portal vein, diammonium glycyrrhizinate (15?mg kg^?1) did not affect any of the pharmacokinetic parameters of aconitine (0.02?mg kg^?1). Thus, diammonium glycyrrhizinate can enhance the absorption of aconitine, leading to higher oral bioavailability and plasma levels, but it does not influence its elimination.

3. Moreover, an in vitro everted gut sac model and Ussing chamber model were used to investigate the potential mechanism. Results from bidirectional transport and inhibition studies demonstrated that P-glycoprotein was the main efflux transporter involved in the absorption of aconitine in rats. The absorption enhancement effect of diammonium glycyrrhizinate should be mainly attributed to inhibiting the activity of P-glycoprotein rather than to the influence on the paracellular or transcellular transport.     

THE PHARMACOKINETICS OF 1954U89, 1, 3-DIAMINO-7-(1-ETHYLPROPYL)-8-METHYL-7H-PYRROLO-(3, 2-f )QUINAZOLINE,IN DOGS AND RATS AFTER INTRAVENOUS AND ORAL ADMINISTRATION

1954U89, 1, 3-diamino-7-(1-ethylpropyl)-8-methyl-7H-pyrrolo-(3, 2-f )quinazoline, is a potent, lipid-soluble inhibitor of dihydrofolate reductase. The pharmacokinetics and bioavailability of 1954U89 were examined in male beagle dogs and male CD rats. Dogs received single intravenous (2·5 mg kg⁻¹) and oral (5·0 mg kg⁻¹) doses of 1954U89 with and without successive administration of calcium leucovorin. Single intravenous (5·0 mg kg⁻¹) and oral (10 mg kg⁻¹) doses of [1,3-¹⁴C₂]1954U89 were administered to rats. Plasma concentrations of total radiocarbon were determined by scintillation counting, and intact 1954U89 was measured by HPLC. The mean plasma half-life was 3·2 ± 0·62 and 4·2 ± 0·68 h after intravenous and oral administration, respectively, to dogs. The pooled plasma half-life after intravenous administration to rats averaged 1·2 h; a reliable plasma half-life value after oral administration could not be determined. Mean total-body clearance was 2·4 ± 0·39 and 4·5 ± 1·1 L h⁻¹ kg⁻¹ after intravenous and oral administration, respectively, to dogs, and averaged 12 and 77 L h⁻¹ kg⁻¹ after intravenous and oral administration, respectively, to rats. Neither clearance nor bioavailability of 1954U89 in dogs was affected significantly by administration of calcium leucovorin. Absolute bioavailability was 54 ± 12% in dogs and 16% in rats. © 1997 John Wiley & Sons, Ltd.