Tolerance to the hypnotic and electroencephalographic effect of gamma-hydroxybutyrate in the rat: pharmacokinetic and pharmacodynamic aspects

Tolerance to gamma-hydroxybutyrate (GHB) has been suggested in illicit users and has been described for the hypnotic effect in the rat. The aim of this study was to investigate whether tolerance is also observed for the EEG effect, and whether the EEG can give insight into the pharmacodynamic aspects of GHB tolerance. In three series of experiments, rats were pre-treated with either the GHB precursor gamma-butyrolactone (GBL) or saline intraperitoneally twice daily. In the first series, a reduction in sleeping time was observed in the GBL pre-treated rats compared with controls. In the second series, a fast infusion of GHB (300 mg kg(-1) over 5 min) was given after 10 days pre-treatment. The GHB plasma concentration-time curves showed a slightly faster decrease in GHB concentration in the GBL pre-treated rats, suggesting a small induction of the GHB metabolism (V(max) = 2882 +/- 457 microg min(-1) kg(-1) vs 2205 +/- 315 microg min(-1) kg(-1), P < 0.01). In contrast to controls, GBL pre-treated rats did not lose righting reflex. In the third series, a slow infusion of 480 mg kg(-1) h(-1) was given after 7 days pre-treatment, which allowed fitting a sigmoid E(max) model to the EEG amplitude versus GHB plasma concentration curve. This showed reduced end-organ sensitivity to GHB in the GBL pre-treated rats (EC50 (concentration required to obtain 50% depression of the baseline effect) = 653+/- 183 microg mL(-1) vs 323 +/- 68 microg mL(-1), P < 0.001). In conclusion, chronic pre-treatment with gamma-butyrolactone in the rat results in a reduced sleeping time and this tolerance is reflected by the EEG. This can mainly be explained by reduced end-organ sensitivity.     

Oral bioavailability in pigs of a miconazole/Hydroxypropyl-γ-cyclodextrin/ L-tataric acid inclusion complex produced by supercritical carbon dioxide processing

The objective of this study was to determine the pharmacokinetic parameters of miconazole after oral administration of a miconazole/hydroxypropyl-gamma-cyclodextrin(HPgammaCD)/L-tartaric acid inclusion complex produced by supercritical carbon dioxide processing. The pharmacokinetics of the miconazole ternary complex (CPLX), of the corresponding physical mixture (PHYS), and of miconazole alone (MICO) were compared after oral administration. Six mixed-breed pigs received each formulation as a single dose (10 mg miconazole/kg) in a crossover design. Miconazole plasma concentrations were determined by a high-performance liquid chromatography method. Preliminary in vitro dissolution data showed that CPLX exhibits a faster and higher dissolution rate than either PHYS or MICO. Following CPLX oral administration, mean area under the plasma concentration curve (AUC(0-infinity)) for miconazole was 95.0 +/- 55.8 microg/min/mL, with the peak plasma concentration (C(max) 0.59 +/- 0.39 microg/mL) at 19.30 minutes. The AUC(0-infinity) and C(max) values were significantly higher than those after oral administration of PHYS (AUC(0-infinity) 38.5 +/- 12.7 microg/min/mL and C(max) 0.24 +/- 0.08 microg/mL; P < .1) and of MICO (AUC(0-infinity) 24.1 +/- 14.0 microg/min/mL and C(max) 0.1 +/- 0.05 microg/mL; P < .1). There were also significant differences between PHYS and MICO (P < .1). The results of the study indicate that CPLX shows improved dissolution properties and a higher relative oral bioavailability compared with PHYS and MICO.     

Pharmacokinetics of a new proton-pump inhibitor, YJA-20379-8, after intravenous and oral administration to rats with streptozotocin-induced diabetes mellitus.

Because physiological changes occurring in diabetes mellitus patients could alter the pharmacokinetics of the drugs used to treat the disease, the pharmacokinetics of a new proton pump inhibitor, YJA-20379-8, were investigated after intravenous and oral administration of the drug (50 mg kg(-1)) to control rats and to rats with streptozotocin-induced diabetes mellitus (SIDM). After intravenous administration of YJA-20379-8 to SIDM rats, plasma concentrations of the drug were significantly higher and this resulted in a significantly greater AUC (area under the concentration-time curve; 2520 +/- 366 compared with 1870+/-272 microg min mL(-1)). This was because of significantly slower clearance (CL; 19.5+/-2.88 compared with 27.2+/-3.93 mL min(-1) kg(-1)) in SIDM rats. The significantly slower metabolism of YJA-20379-8 in SIDM rats was confirmed by an in-vitro tissue metabolism study; the amounts of YJA-20379-8 remaining in the liver (27.1+/-5.19 compared with 18.9+/-8.24 microg(g tissue)(-1)) were significantly greater after 30-min incubation of the drug (50 microg) with supernatant fractions obtained from the tissues by centrifugation at 9000 g. After oral administration of YJA-20379-8 to SIDM rats the plasma concentrations of the drug were significantly lower and this resulted in significantly smaller AUC (128+/-31.0 compared with 219+/-45.6 microg min mL(-1)). This was because of reduced gastrointestinal absorption of YJA-20379-8 in SIDM rats; the amounts of the oral dose recovered as unchanged drug from the entire gastrointestinal tract after 24h were significantly greater (32.9 compared with 19.2%) in SIDM rats. The tissue distribution of YJA-20379-8 was not affected by SIDM.     

Extremely low bioavailability of magnesium lithospermate B, an active component from Salvia miltiorrhiza, in rat

We assessed the bioavailability of magnesium lithospermate B (MLB), a main polyphenolic component of Salvia miltiorrhiza and a potent antioxidant having various pharmacological activities, to evaluate its action in vivo. The plasma concentrations of lithospermic acid B (LSB) showed a biexponential decrease after intravenous administration of MLB to rats at doses of 4 and 20 mg/kg. The values of area under the concentration-time curve (AUC; 87.8 +/- 10.9 and 1130 +/- 329 microg.min/mL), total body clearance (CL (tot); 55.52 +/- 7.07 and 23.51 +/- 5.98 mL/min/kg), and distribution volume at steady state (V (ss); 7.60 +/- 1.03 and 3.61 +/- 1.16 L/kg) suggested non-linear pharmacokinetics between the two doses. After oral administration of MLB at a high dose of 100 mg/kg, the mean AUC was barely 1.26 +/- 0.36 microg.min/mL. Absolute bioavailability of MLB was calculated to be 0.0002 from the AUC values after both intravenous dosing at 20 mg/kg and oral dosing at 100 mg/kg. The extremely low bioavailability was caused mainly by poor absorption from the rat gastrointestinal tract; about 65 % of the dose was retained in the tract even 4 h after oral administration, and most of the dose was retained even 20 min after infusion in an in situ jejunal loop experiment. Urinary and biliary excretion of LSB were only 0.70 % +/- 0.26 % and 5.10 % +/- 2.36 %, respectively, over a 30 h time period after intravenous injection despite the large CL (tot) and V (ss) values, and were much less (0.010 % +/- 0.001 % and 0.12 % +/- 0.04 %) after oral dosing. These findings suggest that extensive metabolism, including a first-pass effect, and wide distribution of LSB besides the poor absorption contributed significantly to the extremely low systemic bioavailability.     

Pharmacokinetic behavior of gentiopicroside from decoction of radix gentianae,gentiana macrophylla after oral administration in rats: A pharmacokinetic comaprison with gentiopicroside after oral and intravenous administration alone

The pharmacokinetics in rats of gentiopicroside (GPS) from orally administered decoctions of Radix Gentianae (DRG) and Gentiana macrophlla (DGM) were compared with that of GPS alone administered at 150 mg/kg orally and 30 mg/kg intravenously. The metabolic profile of GPS after intravenous injection could be fitted to two-compartment model whereas oral administration decoctions DRG or DGM, or GPS alone, could all be fitted to a one-compartment model. After oral administration of GPS alone, GPS was absorbed quickly and reached a maximum plasma concentration (Cmax) value, 5.78 +/- 2.24 microg/mL within 0.75 +/- 0.62 h. The plasma level of GPS declined with a T1/2ke, 3.35 +/- 0.76 h. After oral administration of decoctions DRG and DGM, GPS was absorbed and reached significantly higher maximum concentrations of 10.53 +/- 3.20 microg/mL (p < 0.01) and 7.43 +/- 1.64 microg/mL (p < 0.05) at later time points 1.60 +/- 0.76 (p < 0.01) and 2.08 +/- 0.74 h (p < 0.05), for DRG and DGM respectively, compared with oral GPS alone. Significantly larger AUC values were found for decoctions of GPS (83.49 +/- 20.8 microgxh/mL for DRG and 59.43 +/- 12.9 microgxh/mL for DGM) compared with oral GPS alone (32.67 +/- 12.9 microgxh/mL). The results demonstrate that the bioavailability of GPS was markedly improved when administered as a decoction than as purified GPS. The decoction from Radix Gentianae provided 2.5 times better bioavailability and that from Gentiana macrophlla 1.8 times higher. The study confirms the importance of careful pharmacokinetic analysis in the characterization of herbal medicines when applied for future clinical applications.     

Pharmacokinetics of intravenous and oral DA-8159, a new erectogenic, in rats with protein-calorie malnutrition

Influence of dietary protein deficiency on the pharmacokinetics of DA-8159 and one of its metabolites, DA-8164, was investigated after intravenous and oral administration of DA-8159 at a dose of 30 mg kg(-1) to male Sprague-Dawley rats allowed free access to a 23% (control) or 5% (protein-calorie malnutrition, PCM) casein diet for 4 weeks. The total area under the plasma concentration-time curve from time zero to time infinity (AUC) values of DA-8164 were significantly smaller after both intravenous (87.0 vs 162 microg min mL(-1)) and oral (144 vs 319 microg min mL(-1)) administration of DA-8159 to PCM rats. This could be due to the decrease in CYP3A1/2 (50-60%) in the rats because DA-8164 was mainly formed via CYP3A1/2 in rats. This could be supported by significantly slower in-vitro CL(int) (2.04+/-0.646 vs 3.15+/-0.693 microL min(-1) (mg protein)(-1)) for the formation of DA-8164 in hepatic microsomal fraction of PCM rats. After intravenous administration of DA-8159, the AUC values of DA-8159 were not significantly different between the two groups of rats although the AUC of DA-8164 was significantly smaller in PCM rats, and this may be due to the minor metabolic pathway of DA-8164 in rats. However, after oral administration of DA-8159, the AUC of DA-8159 was significantly greater in PCM rats (194 vs 122 microg min mL(-1)). This was not due to enhanced absorption of DA-8159 from the gastrointestinal tract in the rats but may be due to a decreased intestinal first-pass effect of DA-8159 in the rats.     

The pharmacokinetics of antofloxacin in renally impaired rats

Our aim was to investigate whether renal impairment induced by cisplatin altered the pharmacokinetics of antofloxacin. Antofloxacin (7.5 mg kg(-1), i.v.) was given to normal or renally impaired rats (induced by cisplatin). Concentrations of antofloxacin in plasma and urine were measured using HPLC. Pharmacokinetic parameters were estimated. The plasma concentrations of antofloxacin in the renally impaired rats were significantly higher than those in the normal rats, accompanied by significant increase of the area under the plasma concentration-time curve (AUC) (968.78+/-259.39 microg min mL(-1) versus 509.84+/-46.19 microg min mL(-1) in normal rats P < 0.05). The system clearance (CL) and renal clearance (CL(R)) of antofloxacin decreased from 12.66+/-1.15 mL kg(-1) min(-1) and 3.21+/-1.80 mL kg(-1) min(-1) in normal rats, to 6.63+/-2.82 mL kg(-1) min(-1) and 0.31+/-0.15 mL kg(-1)min(-1), respectively. No differences between two treatments in half-life and mean residence time were found. We concluded that renal impairment induced by cisplatin significantly altered the pharma-cokinetics of antofloxacin and resulted in decrease of the renal elimination.     

Characterization of SAGE Mdr1a (P-gp), Bcrp, and Mrp2 Knockout Rats Using Loperamide, Paclitaxel, Sulfasalazine, and Carboxydichlorofluorescein Pharmacokinetics

Transporter gene knockout rats are practically advantageous over murine models for pharmacokinetic and excretion studies, but their phenotypic characterization is lacking. At present, relevant aspects of pharmacokinetics, metabolism, distribution, and excretion of transporter probes [P-glycoprotein (P-gp): loperamide and paclitaxel; breast cancer resistance protein (Bcrp): sulfasalazine; and multidrug resistance-associated protein 2 (Mrp2): carboxydichlorofluorescein] were studied systematically across SAGE P-gp, Bcrp, and Mrp2 knockout rats. In Mdr1a knockout rats, loperamide and paclitaxel oral bioavailability was 2- and 4-fold increased, respectively, whereas clearance was significantly reduced (40-42%), consistent with the expected 10- to 20-fold reduction in paclitaxel excretion. N-Desmethyl-loperamide pharmacokinetics were not altered in any of the three knockouts after oral loperamide. In rats lacking P-gp, paclitaxel brain partitioning was significantly increased (4-fold). This finding is consistent with observations of loperamide central nervous system opioid pharmacology in Mdr1a knockout rats. Sulfasalazine oral bioavailability was markedly increased 21-fold in Bcrp knockouts and, as expected, was also 2- to 3-fold higher in P-gp and Mrp2 knockout rats. The sulfapyridine metabolite/parent ratio was decreased 10-fold in rats lacking Bcrp after oral, but not intravenous, sulfasalazine administration. Carboxydichlorofluorescein biliary excretion was obliterated in Mrp2 knockout rats, resulting in 25% decreased systemic clearance and 35% increased half-life. In contrast, carboxydichlorofluorescein renal clearance was not impaired in the absence of Mrp2, Bcrp, or P-gp. In conclusion, SAGE Mdr1a, Bcrp, and Mrp2 knockout rats generally demonstrated the expected phenotypes with respect to alterations in pharmacokinetics of relevant probe substrates; therefore, these knockout rats can be used as an alternative to murine models whenever a larger species is practically advantageous or more relevant to the drug discovery/development program.     

Pharmacokinetics of diclofenac in rats intoxicated with CCL4, and in the regenerating liver

The pharmacokinetics of an intravenous and oral diclofenac dose of 3.2 mg/kg was studied in male Wistar rats under control conditions, 1 and 3 days after liver damage and regeneration induced by an oral injection of CCl(4). One day after CCl(4) administration, indicators of necrosis (alanine aminotransferase), cholestasis (gamma-glutamyl transpeptidase) and regeneration (alpha-fetoprotein) were significantly increased; these effects were reversed after 3 days. In nonintoxicated rats, t(1/2) was 43.83 +/- 4.95 min, V(d) was 0.37 +/- 0.04 l/kg, Cl was 129.21 +/- 9.20 ml/min kg, AUC(i.v.) was 25.62 +/- 1.45 microg/min ml, and AUC(p.o.) was 20.21 +/- 1.03. One day after intoxication, when the liver was damaged and regenerating, the metabolism was decreased: diclofenac t(1/2) was increased to 258.21 +/- 30.80 min but V(d) did not change significantly, therefore Cl was reduced to 32.81 +/- 3.38 ml/min kg. By day 3 after intoxication, liver function, regeneration and pharmacokinetics returned to normal. The results show that liver damage and regeneration increases the bioavailability by decreasing elimination. The present observations suggest that reduction of the pharmacokinetic parameters may lead to drug accumulation in the regenerating-damaged liver with an attendant possible increase in toxic effects. The results in rats, also suggest that once hepatic injury is finished and regeneration is complete, diclofenac can be administered normally.     

Effect of 1-aminobenzotriazole on the in vitro metabolism and single-dose pharmacokinetics of chlorzoxazone, a selective CYP2E1 substrate in Wistar rats

The aim of this study was to study the effect of 1-aminobenzotriazole (ABT) on in vitro metabolism, oral, and intravenous (IV) pharmacokinetics of chlorzoxazone (CZX) in rats. Enzyme kinetics of CZX was performed with rat and human liver microsomes and pure isozyme (CYP2E1) with and without ABT. The enzyme kinetics (V(max) and K(m)) of the formation of 6-hydroxychlorzoxazone (OH-CZX) was found to be similar among rat liver microsomes (3486 pmol mg protein(-1) min(-1) and 345 microM), human liver microsomes (3194 pmol mg protein(-1) min(-1) and 335 microM) and pure isozyme (3423 pmol mg protein(-1) min(-1) and 403 microM), but K(I) and K(inact) values for ABT towards the ability to inhibit the formation of OH-CZX from CZX varied between liver microsomes (rat: 32.09 microM and 0.12 min(-1); human: 27.19 microM and 0.14 min(-1)) and pure isozyme (3.18 microM and 0.29 min(-1)). The novel robust analytical method was capable of quantifying CZX, OH-CZX, and ABT simultaneously in a single run, and the method was used for both in vitro and in vivo studies. Pre-treatment of rats with ABT prior to oral and IV administration of CZX significantly decreased the clearance (threefold) and consequently increased the AUC of CZX (approx. three- to fourfold). When rats were pre-treated with ABT, the formation of OH-CZX was completely blocked after oral and IV administration; however, we were able to measure OH-CZX in rats administered with CZX by oral and IV routes without pre-treatment of ABT. The oral bioavailability of CZX was approximately 71% when dosed alone and reached 100% under pre-treatment with ABT. The t(1/2) values of CZX was significantly prolonged for oral dosing compared with IV dosing under pre-treated conditions with ABT, suggesting an involvement of pre-systemic component in the disposition of CZX. The pharmacokinetic parameters of ABT did not change when it was dosed along with CZX (oral and IV), indicating that either CZX or OH-CZX had no effect on disposition of ABT. The plasma concentrations of ABT were above and beyond the required levels to inhibit CYP2E1 enzyme for at least 36 h post-treatment.     

Effect of recombinant interleukin-2 pretreatment on oral and intravenous digoxin pharmacokinetics and P-glycoprotein activity in mice.

P-glycoprotein (P-gp) is an ATP-dependent efflux membrane transporter involved in many drug pharmacokinetics in humans. Decreasing its expression could enhance the bioavailability of substrates as digoxin. We have recently found that human recombinant interleukin-2 (rIL2) in vivo decreases P-gp expression in intestine and brain of mice and modifies oral digoxin pharmacokinetics. The aim of the study was to evaluate the involvement of bioavailability in the rIL2 pretreatment effect on digoxin pharmacokinetics by comparing oral and i.v. digoxin pharmacokinetics before and after rIL2 pretreatment (10 microg/kg). We also tried to show the possible effect of a low rIL2 dose (1 microg/kg) pretreatment on oral digoxin pharmacokinetics. First, adult Swiss mice received a single oral or i.v. dose of digoxin (0.03 mg/kg). Two weeks later, the same animals were treated by rIL2 i.p. twice a day (10 microg/kg) for 4 days and received digoxin again at day 5. As well, another group received oral digoxin (0.03 mg/kg) with a 1 microg/kg rIL2 pretreatment. Blood was collected after digoxin administration with and without rIL2 pretreatment. Digoxin pharmacokinetics were described by a one-compartment model. The 10 microg/kg rIL2 pretreatment did not modify i.v. digoxin pharmacokinetics, whereas oral digoxin pharmacokinetics were significantly modified by the 10 microg/kg rIL2 pretreatment and not by the 1 microg/kg rIL2 pretreatment. The decrease of P-gp activity, caused by rIL2 (10 microg/kg), increased digoxin bioavailability. An increase in exposure and intracellular level of drugs is expected from rIL2 pretreatment.     

Pharmacokinetics and tissue distribution of 8,9-epoxy brevifolin in rats, a hepatoprotective constituent isolated from Phyllanthus simplex Retz by liquid chromatography coupled with mass spectrometry method

8,9-Epoxy brevifolin (EBF) is a novel compound isolated from Phyllanthus simplex Retz (P. simplex) and has been demonstrated to possess a hepatoprotective effect. The purposes of the present study were to examine the in vivo pharmacokinetics and tissue distribution of EBF in rats using a liquid chromatography coupled with mass spectrometry quantitative detection method (LC-MS/MS), with luteolin-7-O-glucoside being employed as an internal standard (IS). The method was validated within the concentration range 20-15 000 ng/ml, and the calibration curves were linear with correlation coefficients of >0.999. The limit of quantitation (LOQ) for EBF was 20 ng/ml. The intra-assay accuracy and precision ranged from 98.7% to 100.2% and 2.19% to 6.25%, respectively, while the inter-assay accuracy and precision ranged from 97.5% to 100.3% and 3.35% to 7.28%, respectively. The method was further applied to assess the pharmacokinetics and oral bioavailability of EBF after intravenous and oral administration in rats. The oral bioavailability of EBF was 12.46 +/- 2.31%. In the tissue distribution assay, its concentration was higher in the heart (13.2 +/- 0.24 microg/g) and liver (14.5 +/- 0.19 microg/g) than in other tissues.     

Pharmacokinetics of cisplatin in analbuminemic rats

The effect of protein binding on the pharmacokinetics of cisplatin (cis-diamminedichloroplatinum (II); CDDP) has been studied in analbuminemic rats, which genetically lack albumins, in comparison with normal rats. CDDP was reported to highly bind to serum components, and the major binder was thought to be an albumin. However, there were no significant differences in the serum disappearance profiles of platinum after intravenous (iv) bolus injection of CDDP to analbuminemic rats as compared with normal rats. The total body clearance, Cl(tot), of platinum in normal rats was 48.7+/-22.0 mL h(-1) (5 mg kg(-1)), 55.9+/-4.04 mL h(-1) (10 mg kg(-1)) and 49.0+/-3.57 mL h(-1) (20 mg kg(-1)), whereas Cl(tot) in analbuminemic rats was 52.0+/-8.48 mL h(-1) (5 mg kg(-1)), 62.9+/-10. 8 mL h(-1) (10 mg kg(-1)) and 62.8+/-6.81 mL h(-1) (20 mg kg(-1)). The serum blood urea nitrogen (BUN) and creatinine levels at 6 h after iv injection were higher in both groups of rats who received CDDP than those of pre-dose level. However, there were no significant differences in the renal function tests between analbuminemic rats and normal rats. The binding of CDDP to the serum samples obtained from analbuminemic rats and normal rats was measured by a centrifuging filtration method. The binding percentages were 68.0+/-5.9% (2.0 microg mL(-1)), 56.8+/-4.1% (5.0 microg mL(-1)) and 64.6+/-4.4% (10.0 microg mL(-1)) in analbuminemic rats and 52.9+/-3.5% (2.0 microg mL(-1)), 52.2+/-3.4% (5.0 microg mL(-1)), 56.9+/-1.9% (10.0 microg mL(-1)) in normal rats. Higher binding percentages were obtained in analbuminemic rats than in normal rats. In vitro binding studies under the two incubation conditions (5 min and 2 h) showed that the binding percentages of CDDP to serum proteins were 59.2+/-3.2% (5 min) and 72.3+/-6.5% (2 h) for albumin, 42.3+/-1.9% (5 min) and 39.5+/-2.5% (2 h) for alpha(1)-acid glycoprotein (AAG) and 51.7+/-5.3% (5 min) and 49. 2+/-1.9% (2 h) for gamma-globulin. From these studies, it was elucidated that albumin is not the major ligand in the rat serum and that other proteins also have important roles in the pharmacokinetics of CDDP.     

Pharmacokinetics of bumetanide following intravenous, intramuscular, and oral administrations to normal subjects

The pharmacokinetics of bumetanide was studied in 12 normal subjects after 1-mg intravenous, intramuscular, oral solution, and tablet administrations in a random four-treatment crossover design. Plasma and urine concentrations of intact bumetanide were analyzed by a sensitive and specific RIA. The pharmacokinetics of bumetanide after intravenous administration was characterized by a biexponential equation, including an initial disposition phase (t 1/2, alpha = 5.1 min), followed by a slower elimination phase (t 1/2, beta = 44 min). Bumetanide pharmacokinetics after intramuscular and oral administration could be described by a biexponential equation with first-order absorption and elimination. Bumetanide is rapidly absorbed via the intramuscular and oral routes, with mean +/- SD maximum plasma concentrations of 38.2 +/- 9.8 (intramuscular), 34.0 +/- 10.6 (oral solution), and 30.9 +/- 14.6 ng/mL (tablet) achieved within 0.34 +/- 0.23, 0.76 +/- 0.27, and 1.8 +/- 1.2 h after dosing, respectively. The drug is rapidly eliminated from the body after intravenous, intramuscular, oral solution, and oral tablet administrations, with half-lives ranging from 24-86, 47-139, 27-71, and 26-99 min, respectively. Approximately 70% of a parenteral dose and 60% of an oral dose are excreted as intact drug in urine taken 0-24 h after administration. The extent of bioavailability of bumetanide from the tablet and oral solution dosage forms are equivalent, and the absolute bioavailability of the intramuscular and oral preparations are approximately 100 and 80%, respectively. This is consistent with the predicted limited extent of first-pass metabolism after complete absorption of an oral dose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Quinidine as a probe for the role of p-glycoprotein in the intestinal absorption and clinical effects of fentanyl

The mechanism of individual variability in the fentanyl dose-effect relationship is unknown. The efflux pump P-glycoprotein (P-gp) regulates brain access and intestinal absorption of numerous drugs. Evidence exists that fentanyl is a P-gp substrate in vitro, and P-gp affects fentanyl analgesia in animals. However, the role of P-gp in human fentanyl disposition and clinical effects is unknown. This investigation tested the hypothesis that plasma concentrations and clinical effects of oral and intravenous fentanyl are greater after inhibition of intestinal and brain P-gp, using the P-gp inhibitor quinidine as an in vivo probe. Two randomized, double-blind, placebo-controlled, balanced, two-period crossover studies were conducted in normal healthy volunteers (6 males and 6 females) after obtaining informed consent. Pupil diameters and/or plasma concentrations of fentanyl and norfentanyl were evaluated after oral or intravenous fentanyl (2.5 microg/kg), dosed 1 hour after oral quinidine (600 mg) or placebo. Quinidine did not alter the magnitude or time to maximum miosis, time-specific pupil diameter, or subjective self-assessments after intravenous fentanyl but did increase the area under the curve (AUC) of miosis versus time (13.6 +/- 5.3 vs. 8.7 +/- 5.0 mm*h, p< 0.05) and decreased the effect of elimination (k(el) 0.35 +/- 0.16 vs. 0.52 +/- 0.24 h(-1), p < 0.05). Quinidine increased oral fentanyl plasma C(max) (0.55 +/- 0.19 vs. 0.21 +/- 0.1 ng/mL) and AUC (1.9 +/- 0.5 vs. 0.7 +/- 0.3 ng*h*mL(-1)) (both p < 0.05) but had no effect on apparent elimination. Plasma norfentanyl/fentanyl AUC ratios were not diminished by quinidine. Quinidine significantly increased maximum miosis after oral fentanyl (3.4 +/- 1.3 vs. 2.3 +/- 1.3 mm, p< 0.05), commensurate with increases in plasma concentrations, but concentration-effect relationships and the rate constant for the transfer between plasma and effect compartment (k(e0)) (1.9 +/- 1.0 vs. 3.6 +/- 2.6 h(-1)) were not significantly different. Quinidine increased oral fentanyl plasma concentrations, suggesting that intestinal P-gp or some other quinidine-sensitive transporter affects the absorption, bioavailability, and hence clinical effects of oral fentanyl. Quinidine had less effect on fentanyl pharmacodynamics, suggesting that if quinidine is an effective inhibitor of brain P-gp, then P-gp appears to have less effect on brain access of fentanyl.     

家犬单剂量和多剂量口服阿昔莫司缓释制剂的药代动力学和生物等效性研究

目的研究阿昔莫司缓释片在家犬体内单剂量和多剂量的药代动力学和生物等效性。方法测定6只家犬单剂量和多剂量口服缓释片和普通胶囊后的血药浓度。结果阿昔莫司的药-时曲线符合非隔室模型。单剂量给药后，缓释片和普通胶囊的AUC分别为(158±30)和(147±37) μg·h·mL^-1；T_max分别为(4.3±0.8)和(2.6±1.3) h；C_max分别为(29±6)和(42±10) μg·mL^-1；T_1/2分别为(2.3±0.7)和(1.60±0.10) h；MRT分别为(6.0±0.8)和(3.9±0.7) h；F_r为(108±16)%。多剂量给药后，缓释片和普通胶囊的AUC分别为(209±23)和(195±26) μg·h·mL^-1；T_max分别为(6.3±0.8)和(3.4±1.5) h；C_max分别为(27±4)和(36±5) μg·mL^-1；Cmin分别为(2.2±1.0)和(0.20±0.20) μg·mL^-1；C_av分别为(8.7±1.0)和(8.1±1.1) μg·mL^-1；FI分别为(293±73)%和(448±91)%；F_r为(114±19)%。结论单剂量实验的双单侧检验结果表明：缓释片和普通胶囊生物等效；缓释片具有良好的缓释效果。多剂量实验结果表明：缓释片和普通胶囊生物等效；缓释片的波动系数优于普通胶囊。     

沙丁胺醇气雾剂在健康受试者体内的药物动力学和相对生物利用度

目的:研究沙丁胺醇气雾剂在健康受试者的药物动力学和生物利用度.方法:十名健康男性志愿者单剂量吸入1.2 mg沙丁胺醇气雾剂或口服沙丁胺醇水溶液.用HPLC法测定人血浆中沙丁胺醇浓度.以非房室模型计算药物动力学参数,计算气雾剂相对水溶液的生物利用度.结果:气雾剂和口服溶液的药物动力学参数如下:T_(max)(0.22±0.07)和(1.8±0.6)h,C_(max)(3.4±1.1)和(3.9±1.4)μg·L~(-1),T_(1/2)(4.5±1.5)和(4.6±1.1)h,AUC_(0-20min)(0.9±0.3)和(0.16±0.10)μg·h·L~(-1).两种给药途径的T_(max)和AUC_(0-20 min)之间差异显著(P<0.01).AUC_(0-20min)(nihal)为 AUC_(0-20 min)(po)的 8倍.沙丁胺醇气雾剂相对口服溶液的生物利用度为 57％±24％.结论:沙丁胺醇气雾剂在人体的吸收过程与口服溶液差异有显著性.     

Ritonavir decreases the nonrenal clearance of digoxin in healthy volunteers with known MDR1 genotypes

Our objective was to examine the influence of ritonavir on P-glycoprotein (P-gp) activity in humans by characterizing the effect of ritonavir on the pharmacokinetics of the P-gp substrate digoxin in individuals with known MDR1 genotypes. Healthy volunteers received a single dose of digoxin 0.4 mg orally before and after 14 days of ritonavir 200 mg twice daily. After each digoxin dose blood and urine were collected over 72 hours and analyzed for digoxin. Digoxin pharmacokinetic parameter values were determined using noncompartmental methods. MDR1 genotypes at positions 3435 and 2677 in exons 26 and 21, respectively, were determined using PCR-RFLP analysis. Ritonavir increased the digoxin AUC(0-72) from 26.20 +/- 8.67 to 31.96 +/- 11.24 ng x h/mL (P = 0.03) and the AUC(0-8) from 6.25 +/- 1.8 to 8.04 +/- 2.22 ng x h/mL (P = 0.02) in 12 subjects. Digoxin oral clearance decreased from 149 +/- 101 mL/h x kg to 105 +/- 57 mL/h x kg (P = 0.04). Other digoxin pharmacokinetic parameter values, including renal clearance, were unaffected by ritonavir. Overall, 75% (9/12) of subjects had higher concentrations of digoxin after ritonavir administration. The majority of subjects were heterozygous at position 3435 (C/T) (6 subjects) and position 2677 (G/T,A) (7 subjects); although data are limited, the effect of ritonavir on digoxin pharmacokinetics appears to occur across all tested MDR1 genotypes. Concomitant low-dose ritonavir reduced the nonrenal clearance of digoxin, thereby increasing its systemic availability. The most likely mechanism for this interaction is ritonavir-associated inhibition of P-gp. Thus, ritonavir can alter the pharmacokinetics of coadministered medications that are P-gp substrates.     

Disposition of tacrolimus in isolated perfused rat liver: influence of troleandomycin, cyclosporine, and gg918.

The disposition of tacrolimus and the influence of cyclosporine, troleandomycin, and GF120918 (GG918, or N-[4-[2-(1,2,3,4-tetrahydro-6,7-dimethoxy-2-isoquinolinyl)-ethyl]-phenyl]-9,10-dihydro-5-methoxy-9-oxo-4-acridine carboxamine) on its hepatic disposition were examined in the isolated perfused rat liver. Livers from groups of rats were perfused in a recirculatory manner following a bolus dose of tacrolimus (100 microg), a substrate for P-glycoprotein (P-gp) and CYP3A, or with felodipine (200 microg), a substrate only for CYP3A. Perfusions of each substrate were also examined in groups of rats in the presence of the inhibitors: troleandomycin (20 microM, CYP3A inhibitor), GG918 (1 microM, P-gp inhibitor), or cyclosporine (10 microM, CYP3A and P-gp inhibitor). In all experiments, perfusate and bile were collected for 60 min. Tacrolimus, felodipine, and their primary metabolites were determined in perfusate and bile by liquid chromatography/tandem mass spectrometry. The area under the curve (AUC) from 0 to 30 min was determined. For the dual CYP3A and P-gp substrate, tacrolimus, AUC +/- S.D. was decreased from control (2,260 +/- 430 ng. min/ml) by GG918 (1,730 +/- 270 ng. min/ml, P < 0.05) and was increased by troleandomycin (5,200 +/- 2,470 ng. min/ml, P < 0.05) and cyclosporine (4,390 +/- 2,080 ng. min/ml, P < 0.05). For the exclusive CYP3A substrate, felodipine, AUC was unchanged from control by GG918 but increased by troleandomycin and cyclosporine. It is concluded that GG918 increased the hepatic exposure of tacrolimus by inhibiting the canalicular P-gp transport, whereas GG918 has no effect on hepatic disposition of felodipine. These results support our hypothesis that the hepatic metabolic clearance of a dual substrate will be increased by inhibiting the efflux transporter.     

Pharmacokinetics and tissue distribution of a water-soluble flavonol triglycoside, CTN986, in mice

The pharmacokinetics and bioavailability of CTN986, a highly water-soluble flavonol triglycoside that has shown interesting antidepressant effects, were determined in mice after intravenous ( I. V.), intraperitoneal ( I. P.) and oral administrations. Concentrations of CTN986 in the biological samples were determined by a validated LC/MS/MS method. Non-compartmental methods were used to perform pharmacokinetic data analysis. The dose-dependent pharmacokinetics of CTN986 was characterized after I. V. administrations (0.16, 0.4 and 1.0 mg/kg) to mice. There was no significant difference in clearance (CL) with increasing dose [252.66 +/- 42.82 mL/h (0.16 mg/kg) versus 241.73 +/- 14.93 mL/h (1.0 mg/kg)] after I. V. administrations. The absolute bioavailability of CTN986 after I. P. and oral administrations was 96.57 % and 1.31 %, respectively. CTN986 was found to distribute widely in the internal organs of mice 10 min after oral dosage, with tissue concentrations in the order of duodenum, stomach, small intestine, kidney, lung, liver, brain, heart and spleen (from the highest to the lowest). In conclusion, CTN986 could be absorbed and extensively distributed into tissues as its intact form in mice.