The purpose of the study was to evaluate pharmacokinetic characteristics of antofloxacin hydrochloride, a new fluoroquinolone antibiotic, during a multiple, intravenous dosing regimen.
Twelve healthy, Chinese male volunteer subjects were each given 300?mg of antofloxacin by intravenous infusion once daily for 7 days. Blood and urine samples were taken at designated time points for analysis of antofloxacin concentration by high-performance liquid chromatography (HPLC). Safety and tolerability were assessed by evaluation of subject complaints, vital signs, electrocardiograms, electroencephalograms, clinical chemistry parameters, haematology and urinalysis and prothrombin time.
The serum steady concentration of antofloxacin was obtained in 96?h after the administration of a daily intravenous dose of 300?mg of the drug. In the present study, the following pharmacokinetic parameters after 7 days of treatment with antofloxacin were determined to be: Cmax 3.81?±?0.66?mg/L, Cmin 0.85?±?0.19?mg/L, AUC0–24 60.51?±?8.30?mg/L·h, Cav 2.52?±?0.35?mg/L, PTF 87.45?±?3.37%, t1/2β 20.34?±?1.88?h. The Cmax and AUC0–24 after 7-day treatment were both higher than after the first dose (by 43% and 110%, respectively). The cumulative urinary elimination of antofloxacin within 96?h after the last dose was about 56%.
During the study, there were neither subject complaints nor significant adverse clinical findings.
Antofloxacin, administered intravenously as a single, daily 300?mg dose for 7 days, demonstrated favourable pharmacokinetic characteristics and tolerability. The results of this study indicate that antofloxacin hydrochloride is suitable for further clinical study.
A recent focus was to investigate whether antofloxacin, an 8-NH2 derivative of levofloxacin, inhibited cytochrome P450 (CYP) 1A2 activity in rats.
Phenacetin, the representative substrate of CYP1A2, was used as the model drug to evaluate the activity of CYP1A2. In an in vivo study, an oral single dose of antofloxacin (20?mg?kg?1) did not affect the pharmacokinetic behaviour of phenacetin, but a multidose (20?mg?kg?1 twice daily for 7.5 days) significantly increased phenacetin’s area under the curve (AUC). In an in vitro study, only when pre-incubated with β-nicotinamide adenine dinucleotide phosphate, a reduced form (NADPH) system in rat liver microsomes, did antofloxacin inhibit phenacetin O-deethylation. The inhibition was NADPH-, pre-incubation time-, and antofloxacin concentration-dependent.
A physiologically based pharmacokinetic model with mechanism-based inhibition was successfully developed for predicting the interaction between antofloxacin and phenacetin in vivo from the in vitro data. The simulated AUC was 1.4-fold of the control, which was near the observed value of 1.6-fold. From the results, it can be concluded that the inhibition of CYP1A2 by antofloxacin is mechanism-based.
This study investigated the pharmacokinetics of thiamphenicol glycinate (TG) and thiamphenicol (TAP) in beagles (n?=?6) after intravenous administration of 50?mg/kg TG hydrochloride. Plasma concentrations of TG and TAP were measured by a HPLC-UV method.
Two-compartment model was selected to describe the pharmacokinetic characteristics of TG and TAP in vivo. Main parameters were as follows: AUC0–∞ of TAP and TG were 16,328?±?1682 µg·min/mL and 3943?±?546 µg·min/mL, respectively. The total plasma clearance (CL) of TG and TAP were 12.7?±?2.0?mL/min/kg and 2.5?±?0.3?mL/min/kg, respectively. Mean residence time (MRT) of TG and TAP were 27.5?±?3.5 and 207.2?±?20.2?min, respectively. The transformative rate constant (k1M) from TG to TAP was 0.0477?±?0.0028?min?1. The elimination rate constant (kM10) from TAP was 0.0238?±?0.0044?min?1. Coefficients of variation (CV) between observed values and predicted ones were 5.9% and 18.2%, respectively. The volume of distribution of the central compartment for TG (VC) and TAP (VCM) were 0.264?±?0.022?L/kg and 0.127?±?0.023?L/kg, respectively.
Pharmacokinetic parameters suggested that TG was presumably cleaved quickly by tissue esterase to release TAP for effectiveness in beagles after administration.
The function and expression of drug transporters, including P-glycoprotein (P-gp) and organic-anion transporting polypeptides (Oatps), have been investigated but it is not well established how variables such as disease processes affect them. Fexofenadine is a substrate of these transporters and it was previously shown that its clearance is reduced in the rat isolated perfused liver following treatment with E.coli lipopolysaccharide (LPS). However, whether this translates to altered fexofenadine pharmacokinetics in vivo is yet to be established.
E.coli LPS at 5?mg/kg or sterile saline (control) was injected intraperitoneally in rats. Oral or intravenous (IV) fexofenadine (10?mg/kg) was administered 24?h later and plasma and urine samples collected for pharmacokinetic analysis.
LPS treatment did not significantly change the pharmacokinetics of IV fexofenadine, although there was a good correlation between weight loss and clearance suggesting reduced clearance in more severely affected animals. However, AUC0–∞ of oral fexofenadine was a significantly higher in LPS-treated animals (13.9?±?9.76 min·µg/ml) compared to controls (5.53?±?1.12 min·µg/ml).
In conclusion, LPS treatment increased the bioavailability of fexofenadine but did not affect other pharmacokinetic parameters. This is consistent with a reduction in hepatic Oatp and/or P-gp for a high extraction ratio drug such as fexofenadine.
As a novel hydrogen sulfide-modulated agent, S-propargyl-L-cysteine (SPRC) is proven to be a potent cardioprotective candidate. Bioavailability and pharmacokinetics of SPRC (20?mg/kg) in beagle dogs after oral and intravenous administrations were investigated in this study. Plasma concentrations of SPRC were measured by a LC-MS/MS method.
Intravenous administration of SPRC (single dose) to beagle dogs gave a mean plasma half-life of 14.7?h, mean clearance of 0.4?ml min?1 kg?1 and mean apparent volume of distribution of 0.56?L/kg. Single oral administration was completely, fast absorbed (Tmax= 0.33?±?0.20?h) with a mean absolute availability of 112% and mean plasma half-life of 16.5?h.
Multiple oral administration (once daily for 10 consecutive days) of SPRC to dogs resulted in steady state plasma drug concentration being reached after seven doses and didn’t cause obvious accumulation. No significant difference was found between the single and multiple pharmacokinetic parameters.
The oral bioavailability of puerarin is poor which hindered its clinical performance.
This study investigates the effects of verapamil on the pharmacokinetics of puerarin in rats.
The pharmacokinetics of orally administered puerarin (50?mg/kg) with or without verapamil pretreatment (10?mg/kg/day for 7?days) were investigated. The plasma concentration of puerarin was determined using LC-MS/MS method, and the pharmacokinetics profiles were calculated and compared. Caco-2 cell transwell model was also used to investigate the effects of verapamil on the transport pf puerarin.
The results showed that when the rats were pretreated with verapamil, the maximum concentration (Cmax) of puerarin increased from 683.7?±?51.2 to 933.5?±?75.8?ng/mL (p?<?0.05), and the area under the concentration-time curve from zero to infinity (AUC0-inf) also increased from 3687.3?±?444.6 to 5006.1?±?658.6?μg·h/L (p?<?0.05). The Caco-2 cell transwell experiments indicated that verapamil could decrease the efflux ratio of puerarin from 1.90 to 1.19 through inhibiting the activity of P-gp.
In conclusion, these results indicated that verapamil could affect the pharmacokinetics of puerarin, possibly by increasing the systemic exposure of puerarin by inhibiting the activity of P-gp.
5-{2-[4-(3,4-Difluorophenoxy)-phenyl]-ethylsulfamoyl}-2-methyl-benzoic acid (1) is a novel, potent, and selective agonist of the peroxisome proliferator-activated receptor alpha (PPAR-α).
In preclinical species, compound 1 demonstrated generally favourable pharmacokinetic properties. Systemic plasma clearance (CLp) after intravenous administration was low in Sprague–Dawley rats (3.2?±?1.4?ml min?1 kg?1) and cynomolgus monkeys (6.1?±?1.6?ml min?1 kg?1) resulting in plasma half-lives of 7.1?±?0.7?h and 9.4?±?0.8?h, respectively. Moderate bioavailability in rats (64%) and monkeys (55%) was observed after oral dosing. In rats, oral pharmacokinetics were dose-dependent over the dose range examined (10 and 50?mg kg?1).
In vitro metabolism studies on 1 in cryopreserved rat, monkey, and human hepatocytes revealed that 1 was metabolized via oxidation and phase II glucuronidation pathways. In rats, a percentage of the dose (approximately 19%) was eliminated via biliary excretion in the unchanged form.
Studies using recombinant human CYP isozymes established that the rate-limiting step in the oxidative metabolism of 1 to the major primary alcohol metabolite M1 was catalysed by CYP3A4.
Compound 1 was greater than 99% bound to plasma proteins in rat, monkey, mouse, and human.
No competitive inhibition of the five major cytochrome P450 enzymes, namely CYP1A2, P4502C9, P4502C19, P4502D6 and P4503A4 (IC50’s?>?30 μM) was discerned with 1.
Because of insignificant turnover of 1 in human liver microsomes and hepatocytes, human clearance was predicted using rat single-species allometric scaling from in vivo data. The steady-state volume was also scaled from rat volume after normalization for protein-binding differences. As such, these estimates were used to predict an efficacious human dose required for 30% lowering of triglycerides.
In order to aid human dose projections, pharmacokinetic/pharmacodynamic relationships for triglyceride lowering by 1 were first established in mice, which allowed an insight into the efficacious concentrations required for maximal triglyceride lowering. Assuming that the pharmacology translated in a quantitative fashion from mouse to human, dose projections were made for humans using mouse pharmacodynamic parameters and the predicted human pharmacokinetic estimates.
First-in-human clinical studies on 1 following oral administration suggested that the human pharmacokinetics/dose predictions were in the range that yielded a favourable pharmacodynamic response.
The metabolism and excretion of a GABAA partial agonist developed for the treatment of anxiety, CP-409,092; 4-oxo-4,5,6,7-tetrahydro-1H-indole-3-carboxylic acid (4-methylaminomethyl-phenyl)-amide, were studied in rats following intravenous and oral administration of a single doses of [14C]CP-409,092.
The pharmacokinetics of CP-409,092 following single intravenous and oral doses of 4 and 15?mg kg?1, respectively, were characterized by high clearance of 169?±?18?ml min?1 kg?1, a volume of distribution of 8.99?±?1.46 l kg?1, and an oral bioavailability of 2.9% ± 3%.
Following oral administration of 100?mg kg?1 [14C]CP-409,092, the total recovery was 89.1% ± 3.2% for male rats and 89.3% ± 0.58% for female rats. Approximately 87% of the radioactivity recovered in urine and faeces were excreted in the first 48?h. A substantial portion of the radioactivity was measured in the faeces as unchanged drug, suggesting poor absorption and/or biliary excretion. There were no significant gender-related quantitative/qualitative differences in the excretion of metabolites in urine or faeces.
The major metabolic pathways of CP-409,092 were hydroxylation(s) at the oxo-tetrahydro-indole moiety and oxidative deamination to form an aldehyde intermediate and subsequent oxidation to form the benzoic acid. The minor metabolic pathways included N-demethylation and subsequent N-acetylation and oxidation.
The present work demonstrates that oxidative deamination at the benzylic amine of CP-409,092 and subsequent oxidation to form the acid metabolite seem to play an important role in the metabolism of the drug, and they contribute to its oral clearance and low exposure.
This work aimed to investigate plasma pharmacokinetics and tissue distribution of a new acridine derivative 5-acridin-9-ylmethylene-3-(4-methyl-benzyl)-thiazolidine-2,4-dione (AC04) and its 1-oxo-AC04 metabolite disposition in Wistar rats.
After a single AC04 1.5?mg/kg intravenous (i.v.) bolus dose, blood samples were taken up to 120?h. Plasma samples were deproteinization, and AC04 and metabolite were quantified by validated liquid chromatography in tandem with mass spectrometry method. Protein binding was determined by ultrafiltration. AC04 tissue disposition was evaluated after i.v. bolus dose.
Individual AC04 concentration–time profiles were best fitted by a two-compartment model showing CLtot of 3.4?±?3.4?L/h/kg, VdSS of 137.9?±?91.4?L/kg, AUC0–∞ of 788?±?483 ng·h/mL and a t1/2 of 45.5?±?31.5?h. Protein binding was 98.1?±?1.6%. AC04 showed higher penetration into the lung, spleen and liver, with AUC0–96 of 798,443, 263,211 and 303,722 ng·h/mL, respectively. The 1-oxo-AC04 metabolite represented 10% of AC04 plasma concentration, showing a t1/2 of 23.2?±?10.4?h.
These results suggest that, despite the small free plasma fraction, AC04 penetrates extensively reaching high concentrations in most tissues residing for a long time, which is important for its activity on solid tumours. All results combined indicate that AC04 is potentially a good antitumour candidate.
A rapid and sensitive method for the determination of isocorydine in rat plasma and tissues was developed using liquid chromatography–tandem mass spectrometry (LC–MS/MS).
The biological samples were processed by extracting with diethyl ether–dichloromethane (3:2, v/v) and tetrahydropulmatine was used as the internal standard (IS). Detection of the analytes was achieved using positive ion mode electrospray ionization in the multiple reaction monitoring mode. The MS/MS ion transitions monitored were m/z 342.0→279.0 and 356.0→191.9 for isocorydine and IS, respectively.
The maximum plasma concentration (Cmax 2496.8?±?374.4 µg/L) was achieved at 0.278?±?0.113?h (Tmax) and the half-life (t1/2) of isocorydine was 0.906?±?0.222?h after a 20?mg/kg oral administration. As for a 2?mg/kg intravenous (i.v.) administration, the Cmax and clearance (CL) were 1843.3?±?338.3 µg/L and 2.381?±?0.356?L/h/kg, respectively. Based on the AUC0–∞ obtained from oral and i.v. administration, the absolute bioavailability (F) was estimated as 33.4%. Tissue distribution results indicated that isocorydine underwent a rapid and wide distribution into tissues and it could effectively cross the blood-brain barrier.
We compared the intrinsic clearance (CLint) of a number of substrates in suspensions of fresh and cryopreserved human hepatocytes from seven donors.
CLint values for a cocktail incubation of phenacetin, diclofenac, diazepam, bufuralol, midazolam, and hydroxycoumarin were 4.9?±?3.4, 18?±?7.2, 5.1?±?4.9, 6.3?±?3.3, 9.8?±?5.8 and 22?±?14?μl min?1/106 cells, respectively, and they correlated well with corresponding CLint values using cryopreserved hepatocytes from 25 different donors.
CLint values of each cocktail substrate and 20 AstraZeneca new chemical entities were compared in fresh and cryopreserved hepatocytes from the same three donors. There was a statistically significant correlation between CLint in fresh and cryopreserved hepatocytes for each of the three livers (p?int values was 1.03.
In conclusion, the results add further support to the use of cryopreserved human hepatocytes as a screening model for the intrinsic clearance of new chemical entities.
Aconite alkaloids are the main bioactive ingredients existing in Aconitum, for instance aconitine (AC), which exhibit potent analgesic, antirheumatic and other pharmacological effects. In this study, effects of long-term treatment with liquorice on pharmacokinetics of AC in rats were investigated.
Pharmacokinetics of AC after oral administration of AC at 1.5?mg/kg either with pre-treatment of liquorice water extracts at 0.433 or 1.299?g/kg (crude drug), respectively, for one week or not were studied. Additionally, LS-180 cells and human primary hepatocytes were utilized to explore the potential effects of bioactive ingredients of liquorice on P-glycoprotein (P-gp) and Cytochromes P450 (CYPs), respectively.
The results revealed that exposure of AC after pre-treatment with liquorice was altered remarkably. Area under the concentration-time curve (AUC) decreased from 161?±?37.8 to 58.8?±?8.97 and 44.7?±?8.20?ng/mL*h, respectively. Similarly, Cmax decreased from 26.2?±?5.19 to 11.8?±?1.15 and 6.86?±?0.600?ng/mL, respectively. In addition, expressions of CYPs of human primary hepatocytes were enhanced to various contents after induction. Moreover, accumulation of AC and hypaconitine (HA), not mesaconitine (MA) inside of LS-180 cells were reduced after pre-treatment by comparison with control.
In conclusion, the exposure of AC in vivo declined after pre-treatment with liquorice extract, which may be highly associated with upregulated expression and/or function of CYPs and P-gp.
Telavancin is an intravenous lipoglycopeptide antibiotic active against many Gram-positive pathogens via inhibition of bacterial cell wall synthesis and disruption of bacterial membrane function.
Non-compartmental pharmacokinetic parameters of telavancin (clearance [Cl], steady-state volume of distribution [Vss], area under the concentration curve [AUC], and elimination half-life [t1/2]) were determined for five preclinical species (mice, rats, rabbits, dogs, and monkeys). Interspecies scaling was applied to predict the corresponding parameters in humans and compare retrospectively with observed values.
Plasma concentrations of single doses of telavancin declined monoexponentially in all species with half-lives between 1.2 and 2.4?h. The pharmacokinetics of telavancin was demonstrated to be dose-proportional in rabbits and gender-independent in monkeys.
Application of the simple allometric equation (Y?=?aWb) resulted in a good correlation between predicted and observed values of Vss in humans. Application of a modified allometric equation that includes brain weight (Cl?×?BW?=?aWb) resulted in a good correlation between predicted and observed values of Cl, AUC, and t1/2 in humans.
These data suggest that interspecies scaling may be useful to predict pharmacokinetic parameters of telavancin in humans.
Radix Ophiopogonis is often an integral part of many traditional Chinese formulas, such as Shenmai injection used to treat cardio-cerebrovascular diseases. This study aimed to investigate the influence of the four active components of Radix Ophiopogonis on the transport activity of OATP1B1 and OATP1B3.
The uptake of rosuvastatin in OATP1B1-HEK293T cells were stimulated by methylophiopogonanone A (MA) and ophiopogonin D′ (OPD′) with EC50 calculated to be 11.33?±?2.78 and 4.62?±?0.64?μM, respectively. However, there were no remarkable influences on rosuvastatin uptake in the presence of methylophiopogonanone B (MB) or ophiopogonin D (OPD). The uptake of atorvastatin in OATP1B1-HEK293T cells can be increased by MA, MB, OPD and OPD′ with EC50 calculated to be 6.00?±?1.60, 13.64?±?4.07, 10.41?±?1.28 and 3.68?±?0.85?μM, respectively.
The uptake of rosuvastatin in OATP1B3-HEK293T cells was scarcely influenced by MA, MB and OPD, but was considerably increased by OPD′ with an EC50 of 14.95?±?1.62?μM. However, the uptake of telmisartan in OATP1B3-HEK293T cells was notably reduced by OPD′ with an IC50 of 4.44?±?1.10?μM, and barely affected by MA, MB and OPD.
The four active components of Radix Ophiopogonis affect the transporting activitives of OATP1B1 and OATP1B3 in a substrate-dependent manner.
Reactivity of benzene oxide (BO), a reactive metabolite of benzene, was studied in model reactions with biologically relevant S- and N-nucleophiles by LC-ESI-MS.
Reaction with N-acetylcysteine (NAC) in aqueous buffer solutions gave N-acetyl-S-(6-hydroxycyclohexa-2,4-dien-1-yl)cysteine (pre-phenylmercapturic acid, PPhMA), which was easily dehydrated in acidic solutions to phenylmercapturic acid (PhMA). The yield of PPhMA + PhMA increased exponentially with pH up to 11% in the pH range from 5.5 to 11.4.
Primary 6-hydroxycyclohexa-2,4-dien-1-yl (HC) adducts were detected also in reactions of purine nucleosides and nucleotides under physiological conditions. After a vigorous acidic hydrolysis, all HC adducts were converted to corresponding phenyl purines, which were identified as 7-phenylguanine (7-PhG), 3-phenyladenine (3-PhA) and N6-phenyladenine (6-PhA). The yield of 7-PhG amounted to 14?±?5 and 16?±?7?ppm for 2′-deoxyguanosine and 2′-deoxyguanosine-5′-monophosphate, respectively, that of 6-PhA was 500?±?70 and 455?±?75?ppm with 2′-deoxyadenosine and 2′-deoxyadenosine-5′-phosphate, respectively, with only traces of 3-PhA.
Reactions with the DNA followed by acidic hydrolysis yielded 26?±?11?ppm (mean ± SD; n?=?9) of 7-PhG as the sole adduct detected.
In contrast to the reactions with S-nucleophiles, the reactivity of BO with nucleophilic sites in the DNA is very low and can therefore hardly account for a significant DNA damage caused by benzene.
The aim of this investigation was to determine the pharmacokinetics and demethylation of caffeine (CF) and the metabolite/CF ratios that correlated best with CF clearance, which were used to evaluate hepatic drug-oxidizing capacity of CF after a single intravenous dose (5?mg/kg) in hair goats (n?=?9).
Pharmacokinetic parameters of CF and its metabolites, theobromine (TB), paraxanthine (PX) and theophylline (TP), were calculated. The plasma metabolic ratios TB/CF, PX/CF, TP/CF and TB+PX+TP/CF were determined at 6, 8 and 10?h after CF administration to evaluate their hepatic drug-oxidizing capacity.
The plasma concentration–time data of CF were fit to a two-compartment model in all animals. The clearance of CF was 0.08?±?0.02?L/h/kg, and the volume of distribution was 0.91?±?0.16?L/kg. The demethylation fractions of CF to TB, PX and TP were 0.24, 0.37 and 0.39, respectively.
Correlations between the metabolic ratios and CF clearance were quite high, except for the PX/CF ratio, particularly at 6?h (r?=?0.650–0.750, P?<?0.01, 0.05) and 10?h (r?=?0.650–0.767, P?<?0.01, 0.05).
Plasma metabolite/CF ratios, except for the PX/CF ratio, may be useful as an alternative to measurements of CF clearance for the determination of the hepatic drug-oxidizing capacity in goats.
In order to sort out the involvement of cytochrome P450 (CYP) 3A and possibly CYP2B in testosterone hydroxylation in cattle, enzyme kinetic and inhibition studies were performed.
Most relevant kinetic constants (Km and Vmax) for 6β-, 16β- and 2β-testosterone hydroxylase (OHT) activities were determined and accounted for 93.4?±?13.8, 36.4?±?6.1 and 110.8?±?15.2?μM, respectively, for Km and 0.558?±?0.03, 0.280?±?0.013, and 0.338?±?0.017?nmol min–1 mg–1 protein, respectively, for Vmax. Eadie–Hofstee plot analysis pointed out how these enzymatic activities in cattle follow a monophasic kinetic pattern.
Preliminary inhibition studies conducted with the CYP3A inhibitor ketoconazole and the CYP2B inhibitors orphenadrine and 9-ethynylphenanthrene seemed to suggest the major involvement of CYP3A in testosterone hydroxylation in cattle.
Immuno-inhibition studies with an anti-peptide antibody against bovine CYP3A4 confirmed the predominant role of CYP3A in testosterone hydroxylation in bovine liver, proving the usefulness of anti-peptide antibodies in defining the contribution of specific P450 isoforms in drug metabolism in veterinary species.
Commonly used herbal supplements were screened for their potential to inhibit UGT1A1 activity using human liver microsomes. Extracts screened included ginseng, echinacea, black cohosh, milk thistle, garlic, valerian, saw palmetto, and green tea epigallocatechin gallate (EGCG). Estradiol-3-O-glucuronide (E-3-G) formation was used as the index of UGT1A1 activity.
All herbal extracts except garlic showed inhibition of UGT1A1 activity at one or more of the three concentrations tested. A volume per dose index (VDI) was calculated to estimate the volume in which the daily dose should be diluted to obtain an IC50-equivalent concentration. EGCG, echinacea, saw palmetto, and milk thistle had VDI values >2.0?L per dose unit, suggesting a higher potential for interaction.
Inhibition curves were constructed for EGCG, echinacea, saw palmetto, and milk thistle. IC50 values were (mean ± SE) 7.8?±?0.9, 211.7?±?43.5, 55.2?±?9.2, and 30.4?±?6.9 µg/ml for EGCG, echinacea, saw palmetto, and milk thistle extracts, respectively.
Based on our findings, inhibition of UGT1A1 by milk thistle and EGCG and to a lesser extent by echinacea and saw palmetto is plausible, particularly in the intestine where higher extract concentrations are anticipated. Further clinical studies are warranted.
Cytoprotective effects of liquiritigenin (LQ) against liver injuries have been reported, but its pharmacokinetics has not been studied in acute hepatitis. Thus, pharmacokinetics of LQ and its two conjugated glucuronide metabolites: 4′-O-glucuronide (M1) and 7-O-glucuronide (M2), in rats with acute hepatitis induced by d-galactosamine/lipopolysaccharide (GalN/LPS) rats or carbon tetrachloride-treated (CCl4-treated) rats were evaluated.
LQ was administered intravenously (20?mg kg?1) and orally (50?mg kg?1) to control GalN/LPS and CCl4-treated rats. Expression of uridine 5′-diphospho-glucuronosyltransferases 1A (UGT1A) and in vitro metabolism of LQ in hepatic and intestinal microsomes were also measured.
After intravenous administration of LQ, area under the plasma concentration-time curve (AUC) of LQ in GalN/LPS rats was significantly smaller than that in controls due to faster non-renal clearance, as a result of its greater free fraction in plasma and faster hepatic blood flow rate than the controls. In CCl4-treated rats, the AUCM1, 0?8 h/AUCLQ and AUCM2, 0?8 h/AUCLQ ratios were significantly greater than the controls due to decrease in biliary excretion of M1 and M2. However, no significant pharmacokinetic changes were observed in both acute hepatitis rats after oral administration due to comparable intestinal metabolism of LQ.
Modification of oral dosage regimen of LQ may not be necessary in patients with acute hepatitis; but human studies are required.
The purpose of the study was to elucidate the influence of multidrug resistance gene (MDR1) haplotype and CYP3A5 genotype on cyclosporine (CsA) blood level in Chinese renal transplant recipients.
CsA trough level (C0) and peak level (C2) of 115 patients 1 week and 1 month after renal transplantation were determined. MDR1 C1236T, G2677T/A, C3435T and CYP3A5*3 genotypes were determined by polymerase chain reaction (PCR) assays based on amplification refractory mutation.
Dose-adjusted C0 (C0/D), C2 (C2/D) were 50.5?±?22.5, 267.8?±?110.1 ng·kg·(ml·mg)?1 after 1 week of therapy, and 79.3?±?29.4, 406.0?±?135.3 ng·kg·(ml·mg)?1 after 1 month of therapy. Frequencies of MDR1 haplotype TTT, CGC, and TGC were 27.0%, 25.2% and 20.0%, respectively. After 1 month of therapy, C2/D of TTT/TTT patients were 30% (p = 0.057) and 53% (p = 0.003) higher than CGC/TTT and CGC/CGC patients. C0/D of CYP3A5 *1/*1, *1/*3 and *3/*3 patients after 1 month of therapy were 51.8?±?25.0, 71.5?±?27.6, and 86.7?±?28.6 ng·kg·(ml·mg)?1 (p < 0.05).
MDR1 haplotypes and CYP3A5*3 genotypes can be related to C2 and C0 of CsA, respectively.