Pharmacokinetic and pharmacodynamic interactions between simvastatin and diltiazem in patients with hypercholesterolemia and hypertension

Pharmacokinetic and pharmacodynamic interactions between simvastatin, a 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor, and diltiazem, a calcium antagonist, were investigated in 7 male and 4 female patients with hypercholesterolemia and hypertension. The patients were given, for one in a three consecutive 4-week periods, oral simvastatin (5 mg/day), oral simvastatin (5 mg/day) combined with diltiazem (90 mg/day), and then oral diltiazem (90 mg/day), respectively. The area under the plasma concentration versus time curve up to 6 hours post-dose (AUC0-6h) and maximum plasma concentrations (Cmax) of the drugs, serum lipid profiles, blood pressures and liver functions were assessed on the last day of each of the three 4-week periods. After the combined treatment period, Cmax of HMG-CoA reductase inhibitor was elevated from 7.8 +/- 2.6 ng/ml to 15.4 +/- 7.9 ng/ml (P < 0.01) and AUC0-6h from 21.7 +/- 4.9 ng x hr/ml to 43.3 +/- 23.4 ng x hr/ml (P < 0.01), while Cmax of diltiazem was decreased from 74.2 +/- 36.4 ng/ml to 58.6 +/- 18.9 ng/ml (P < 0.05) and its AUC0-6h from 365 +/- 153 ng x hr/ml to 287 +/- 113 ng x hr/ml (P < 0.01). Compared to simvastatin monotherapy, combined treatment further reduced LDL-cholesterol levels by 9%, from 129 +/- 16 mg/dl to 119 +/- 17 mg/dl (P < 0.05). No adverse events were observed throughout the study. These apparent pharmacokinetic interactions, namely the increase of HMG-CoA reductase inhibitor concentration by diltiazem and the decrease of diltiazem concentration by simvastatin, enhance the cholesterol-lowering effects of simvastatin during combined treatment.     

Therapeutic evaluation of sustained-releasing praziquantel (SRP) for clonorchiasis: phase 1 and 2 clinical studies

Sustained-releasing praziquantel (SRP) tablet was designed for single dose treatment regimen of clonorchiasis. A previous pre-clinical study confirmed its sustained-releasing characteristics and a better cure rate than conventional praziquantel (PZQ). In this clinical study, the pharmacokinetics of this SRP tablet were investigated in human volunteers (phase 1; 12 volunteers), and its curative efficacy was examined in clonorchiasis patients (phase 2; 20 volunteers). In the phase 1 clinical study, blood concentrations of both tablets showed wide individual variation. The AUClast of SRP was 497.9 +/- 519.0 ng * hr/ml (mean +/- SD) and PZQ of 628.6 +/- 695.5 ng * hr/ml, and the AUCinf of SRP was 776.0 +/- 538.5 ng * hr/ml and of PZQ 658.6 +/- 709.9 ng * hr/ml. Cmax values of SRP and PZQ were 90.7 +/- 82.2 ng/ml and 214.9 +/- 251.9 ng/ml, and Tmax values were 3.42 +/- 1.43 hr and 1.96 +/- 1.23 hr, respectively. SRP tablets showed similar AUC values, but lower Cmax and longer Tmax values than PZQ. In the phase 2 study, SRP at 30 mg/kg (single dose) achieved a 60% cure rate and a 95.5% egg reduction rate. The cure rate of a single dose SRP was unsatisfactory compared with that of the conventional PZQ dose, but much better than that achieved by a single dose PZQ.     

Pharmacokinetics of methimazole in normal subjects and hyperthyroid patients

Serum and urinary concentrations of methimazole (MMI) were measured by high-performance liquid chromatography (HPLC) with an electrochemical detector (ECD) in 10 normal subjects and 43 hyperthyroid patients after intravenous and oral administration of the drug. The pharmacokinetic parameters of MMI were estimated in 5 normal subjects and 15 hyperthyroid patients according to a two-compartment model after intravenous injection of a 10 mg dose. The mean half-life of the distribution phase (T1/2 alpha) was 2.7 +/- 1.0 h (mean +/- SD) and 3.1 +/- 1.4 h and that of the slower-phase (T1/2 beta) was 20.7 +/- 9.6 h and 18.5 +/- 12.9 h in normal subjects and hyperthyroid patients, respectively. There were no significant differences between pharmacokinetic parameters of normal subjects and those of hyperthyroid patients. No correlations between free T4 index (FT4I) and pharmacokinetic parameters were observed. Maximum serum MMI concentrations (Cmax) (213 +/- 84 and 299 +/- 92 ng/ml) were attained 1.8 +/- 1.4 h and 2.3 +/- 0.8 h after a single dose of 10 mg in 5 normal subjects and in 15 hyperthyroid patients, respectively. In hyperthyroid patients the time taken to reach the peak concentration (Tmax) after a single dose of 10 mg was similar to that after a single 15 mg and 30 mg dose. The pharmacokinetic parameters, except Cmax and the area under the curve (AUC), were not affected by the administered dose and those, except Cmax, were not affected by the thyroid function. All urine was collected at intervals of 3 h for the first 12 h and then at 24 h and 48 h after intravenous and oral administration of MMI. In all subjects, MMI rapidly appeared in the urine and the rate of excretion was highest in the first 3 h. The cumulative urinary excretion of MMI was 5.5-8.5% of administered doses in normal subjects and hyperthyroid patients. These findings in the present study are compatible with the assumption that the extent of absorption of MMI is high, if not complete, and hyperthyroidism does not affect the kinetics of MMI, and that interindividual variation is observed in the time taken to reach the peak concentration after oral administration.     

Oral bioavailability of active principles from herbal products in humans. A study on Hypericum perforatum extracts using the soft gelatin capsule technology.

The oral absorption of two known active principles of Hypericum perforatum, namely hyperforin and hypericin, was studied in an open, single dose, two-way, randomized, cross-over study involving 12 healthy subjects (six males and six females). Alcoholic Hypericum extract (300 mg, containing 5% hyperforin and 0.3 % hypericin) was administered in the morning after 12 hours fasting. The formulation was administered as softgel capsules containing, inter alia, soya oil together with the herbal extract. A second standard formulation in two piece hard gelatin capsules was also used for comparison purposes. Blood was sampled from the subjects at different times after drug administration and the plasma was analysed according to published analytical methods for the determination of hyperforin and hypericin. Peaks of plasma concentration, Cmax of hyperforin were 168.35 ng/ml +/- 57.79 for the soft gelatin formulation (CV=34.32, n=12) and 84.25 ng/ml +/- 33.51 for the hard gelatin capsule (CV=39.77, n=12). The Tmax values for hyperforin were 2.50 h +/- 0.83 for the soft gelatin formulation compared to 3.08 h +/- 0.79 for the reference formulation, whereas the total AUC were respectively 1482.7 h x ng/ml +/- 897.13 and 583.65 h x ng/ml +/- 240.29. As for hypericin, plasma levels were detectable in approximately half of the subjects treated. However also in this case the soft gelatin capsules exhibited a higher individual absorption when compared with the corresponding data for the hard gelatin capsules.     

Pharmacokinetic study of orphenadrine using high-performance liquid chromatography-tandem mass spectrometry (HPLC-MS/MS)

We developed and validated a simple, rapid, and accurate HPLC-MS/MS method with simple protein precipitation for the determination of orphenadrine. Injection-to-injection running time was 3 min with a retention time of orphenadrine of 1.1 min. The linear assay range was 1-200 ng/mL (r2 > 0.99). The intra- and inter-assay imprecisions were CV 0.6-4.2% and CV 1.6-6.1%, respectively. The accuracy, extraction recovery, specificity and stability were satisfactory. Using the measured plasma concentrations of orphenadrine in 24 healthy subjects, pharmacokinetic profiles of orphenadrine were evaluated (AUC(0-72,) 1565+/-731 ng h/mL, Cmax 82.8+/-26.2 ng/mL, Tmax 3.0+/-0.9 h, elimination half-life 25.8+/-10.3 h).     

A capillary gas chromatography-selected ion monitoring mass spectrometry method for the analysis of atractylenolide I in rat plasma and tissues, and application in a pharmacokinetic study

The aim of this paper is to investigate the characteristics of atractylenolide I (AO-I) in the body by a GC-MS method. All bio-samples were cleared up with a liquid-liquid extraction procedure. The calibration curves were linear within a range of 5-1000 ng/mL for plasma samples, 0.06-16.00 microg/g for cerebellum samples, and 0.03-8.00 microg/g for other tissue samples. The limit of quantification (LOQ) for AO-I was 1.0 ng/mL or 1.0 ng/g (S/N>micro=10) in the bio-samples. In the applications, the main pharmacokinetic parameters were firstly obtained as follows: Tmax=0.37+/-0.19 h, Cmax=0.26+/-0.05 microg/mL, AUC=1.95+/-0.30 microgh/mL and ka=10.08+/-5.60 h(-1). The tissue distribution of AO-I in rats after the oral administration of 50.0mg/kg was from 0.225 to 0.031microg/g with a decreasing tendency in different tissues like liver>kidney>spleen>cerebellum>heart>cerebrum>lung. The protein binding in rat plasma, human plasma and bovine serum albumin was 80.8+/-3.9, 90.6+/-3.1 and 60.9+/-5.1%, respectively.     

A new high performance liquid chromatographic method for quantification of atomoxetine in human plasma and its application for pharmacokinetic study

Atomoxetine is the first, non-stimulant alternative to other stimulant medications used for the treatment of Attention-Deficit/Hyperactivity Disorder (ADHD). Reported methods for the determination of atomoxetine include expensive liquid chromatography tandem mass spectrometry (LCMS) and high performance liquid chromatography (HPLC) with liquid scintillation counting (LSC) detection. Till date, no method has been reported in literature to determine atomoxetine using HPLC with UV detection. In this paper, we describe a new HPLC method for the determination of atomoxetine using liquid-liquid extraction with tertiary butyl methyl ether and UV detector. This method was found to be linear over the concentration range of 0.05-3.0 microg/ml. The limit of quantification was 0.05 microg/ml. Intra- and inter-day precision was <15% and accuracy was in the range of 95.67-108.80%. Stability studies showed that atomoxetine was stable in human plasma for short- and long-term period for sample preparation and analysis. This method was used for sample analysis in a pharmacokinetic study of atomoxetine (25mg) in five healthy adult female volunteers. The observed mean+/-S.D. pharmacokinetic parameters Cmax, Tmax and AUC(0-t) were 0.40+/-0.06 microg/ml, 3.40+/-0.42 h and 1.34+/-0.52 microg h/ml, respectively.     

Rapid and sensitive determination of sertraline in human plasma using gas chromatography-mass spectrometry

A method for the determination of sertraline in human plasma using gas chromatography-mass spectrometry (GC-MS), with the selected ion-monitoring (SIM) mode, was described. The following was used in this study: (1) single liquid-liquid extraction at alkaline pH after deproteinization of plasma protein and (2) perfluoroacylation with HFBA, which has higher sensitivity (about 10-fold) compared with previous reported derivatization. The detection limit for the SIM of sertraline as an N-HFB derivative was 0.1 ng/ml, and its recovery was 80-85%. The linear response was obtained in the range of 0.2-10.0 ng/ml with a correlation coefficient of 0.999. The coefficient of variation (C.V.%) was less than 12.1% in the 1-30 ng/ml, and less than 18.2% at 0.2 ng/ml, and the accuracy was less than 10% at all of the concentration range. These findings indicate that this assay method has adequate precision and accuracy to determine the amount of sertraline in human plasma. After pharmacokinetics was performed with this assay method following oral administration of sertraline hydrochloride in man, moment analysis revealed that pharmacokinetic parameters for sertraline (Cmax, 10.3 ng/ml; Tmax, 8.0 h; T(1/2) 28.6 h) were similar to previously reported results. These results indicate that this simple and sensitive assay method is readily applicable to the pharmacokinetic studies of sertraline.     

Pharmacokinetics of florfenicol in cod Gadus morhua and in vitro antibacterial activity against Vibrio anguillarum

The pharmacokinetic profile of the antibacterial agent florfenicol was studied in plasma after intravenous (i.v.) injection and in plasma, muscle and liver following oral (p.o.) administration to cod Gadus morhua, held in seawater at 8 degrees C and weighing 100 to 200 g. Following i.v. injection, the plasma drug concentration-time profile showed 2 distinct phases. The plasma distribution half-life (t1/2alpha) was estimated to be 1.6 h, the elimination half-life (t1/2beta) to be 43 h, the total body clearance (ClT) to be 0.015 1 kg(-1) h(-1) and mean residence time (MRT) to be 74 h. The volume of distribution at steady state, Vd(ss), was calculated to be 1.1 l kg(-1). Following p.o. administration, the bioavailability was estimated to be 91%, the peak plasma concentrations (Cmax) to be 10.8 microg ml(-1) and the time to peak plasma concentrations (Tmax) to be 7 h. Corresponding Cmax and Tmax values were 13.0 microg g(-1) and 9 h, respectively, in muscle and 12.1 microg g(-1) and 9 h, respectively, in liver. The in vitro minimum inhibitory concentration (MIC) values of florfenicol against 3 Vibrio anguillarum strains isolated from diseased cod (A-21, HI-610, HI-618) were 0.5 microg ml(-1) for all 3 strains.     

Quantitative determination of trimebutine maleate and its three metabolites in human plasma by liquid chromatography-tandem mass spectrometry

A sensitive and selective HPLC-MS-MS method was developed for the determination of trimebutine maleate (TM) and its major metabolites N-monodemethyltrimebutine (TM-MPB), N-didemethyltrimebutine (APB) and 3,4,5-trimethoxybenzoic acid (TMBA) in human plasma. The analytes were extracted from plasma samples by liquid-liquid extraction and chromatographed on a YMC J'sphere C(18) column. The mobile phase consisted of 2 mM ammonium acetate buffer (pH 6.5)-methanol (20:80, v/v), and at a flow-rate of 0.2 ml/min. Detection was carried out on a triple quadrupole tandem mass spectrometer in multiple reactions monitoring (MRM) mode using positive-negative switching electrospray ionization (ESI). The method was validated over the concentration range of 1-100 ng/ml for trimebutine maleate and APB, 1-500 ng/ml for MPB, and 50-10,000 ng/ml for TMBA. Inter- and intra-day precision (RSD%) for trimebutine maleate and its three metabolites were all within +/-15% and the accuracy was within 85-115%. The limit of quantitation was 1 ng/ml for trimebutine maleate, TM-MPB and APB, and 50 ng/ml for TMBA. The extraction recovery was on average 58.2% for trimebutine maleate, 69.6% for MPB, 51.2% for APB and 62.5% for TMBA. The method was applied to the pharmacokinetic study of trimebutine maleate and its metabolites in healthy Chinese volunteers.     

Stereospecific versus nonstereospecific assessments for the bioequivalence of two formulations of racemic chlorpheniramine

Chlorpheniramine (chlorphenamine, CPAM) is a racemic antihistaminic H1 drug containing two enantiomers. The aim of this study was to assess the bioequivalence of two formulations (reference and Vietnamese-tested formulation) of racemic chlorpheniramine combined with phenylpropanolamine in an open-labeled, randomized, crossover two-period study, after administration of 8 mg of racemic chlorpheniramine in 12 healthy Vietnamese subjects. First, dissolution of both formulations was tested in vitro according to USP requirements. Then the 12 subjects received both formulations after an overnight fast and a 7-day wash-out period. Plasma samples were collected up to 168 h. Plasma concentrations of total chlorpheniramine and its individual enantiomers were determined with a validated chiral HPLC method and pharmacokinetic parameters were estimated using model-independent analysis. For the reference formulation, Cmax and AUC values were higher for (+)S-chlorpheniramine ((+)S-CPAM) compared to (-)R-chlorpheniramine ((-)R-CPAM) (13.3 vs. 6.8 ng/ml and 409 vs. 222 ng/ml/h, respectively) while Clt/F and Vd/F were lower (9.8 vs. 17.6 l/h and 321 vs. 627 l, respectively). No difference was observed for Tmax, t(1/2), and MRT. Pharmacokinetic parameters were similar for the reference and the Vietnamese-tested formulation. Bioequivalence was assessed by Schuirmann test, as recommended by the current FDA and European Community criteria. Dissolution tests showed that both formulations were equivalent. A nonstereospecific, but not a stereospecific, approach indicated bioequivalence between the formulations.     

Pharmacokinetics of HZ08 in rats by liquid chromatography-tandem mass spectrometry

A selective and sensitive liquid chromatographic method coupled with ion spray tandem mass spectrometry detection (LC-MS/MS) was developed for the determination and pharmacokinetic study of N-cyano-1-[(3,4-dimethoxyphenyl)methyl]-3,4-dihydro-6,7-dimethoxy-N'-octyl-2(1H)-isoquinoline-carboximidamide (HZ08, a candidate reversing agent for multidrug resistance of cancer) liposome injection in rat plasma. The analyte was extracted from plasma using liquid-liquid extraction by methyl tert-butyl ether with drotaverine as internal standard. The chromatographic separation was performed on a Kromasil-C18 column (150 mm x 4.6 mm, i.d., 5 microm) with gradient elution. The tandem mass detection was made with electrospray ionization in positive ion selected reaction monitoring mode with argon collision-induced dissociation. The ion transitions were m/z 523.1 to 342.1 for HZ08 at 27eV and m/z 398.1 to 326.1 at 35eV for the internal standard, respectively. The determination was validated to be accurate and precise for the analysis in the concentration range of 5-10,000 ng/ml for HZ08 with the lower limit of detection (LOD) being 1 ng/ml, when 0.1 ml of rat plasma sample was processed. The main pharmacokinetic parameters found for HZ08 after intravenous (i.v.) administration of its liposome injection at doses of 2, 4 and 8 mg/kg were as follows: C(max) (4511+/-681), (5553+/-1600) and (6444+/-950) ng/ml, T(max) (0.033+/-0), (0.056+/-0.048) and (0.033+/-0) h, t(1/2) (1.75+/-0.19), (1.63+/-0.12) and (1.56+/-0.18) h, AUC(0-6) (899+/-112), (1238+/-190) and (1707+/-307) h ng/ml, AUC(0-infinity) (917+/-110), (1256+/-189) and (1723+/-306) h ng/ml, MRT (1.14+/-0.21), (1.01+/-0.13) and (1.16+/-0.17) h, CL (2.90+/-0.15), (3.01+/-0.74) and (4.11+/-0.59)l/h/kg, respectively. The plasma concentration-time profiles of HZ08 were best fitted with two-compartment models. Linear pharmacokinetics was found for HZ08 in rats after intravenous administration of the liposome injection.     

Determination of disodium clodronate in human plasma and urine using gas-chromatography-nitrogen-phosphorous detections: validation and application in pharmacokinetic study

We present a specific method for the determination of disodium clodronate in human plasma and urine using a gas-chromatographic system with nitrogen phosphorus detector (NPD). The compound was extracted from plasma and urine samples by an anion-exchange resin and derivatizated with bistrimethylsilyltrifluoroacetamide (BSTFA). Sodium bromobisphosphonate was used as internal standard. The calibration curves were linear in both plasma and urine, with a regression coefficient r > 0.9975 in plasma and r > 0.9977 in urine.The limit of quantitation was 0.3 microg/ml in plasma and 0.5 microg/ml in urine. The method was validated by intra-day assays at three concentration levels. During the study we carried out inter-day assays to confirm the feasibility of the method. The precision in plasma at 0.5, 15, and 45 microg/ml was 12.4, 0.2, and 6.5% (n = 40), respectively; in urine at 0.8, 8, and 40 microg/ml it was 8.6, 6.4, and 9.3% (n = 40), respectively.The method was accurate and reproducible, and was successfully applied to determine the pharmacokinetic parameters of clodronate in healthy volunteers after intravenous infusion and intramuscular injection of 200 mg of the compound. The Cmax after intravenous infusion and intramuscular injection was 16.1 and 12.8 microg/ml, respectively. AUC(0-48 h) after infusion administration and intramuscular injection was 44.2 +/- 18.0 and 47.5 +/- 12.4 h microg/ml, respectively. The elimination half-life in both administrations was 6.31 +/- 2.7 h.     

孟鲁斯特钠咀嚼片在健康人体内药动学和生物等效性

目的:研究两种(仿制新药与市售)孟鲁司特钠咀嚼片在人体内生物等效性。方法:采用单中心、随机、开放、双周期自身交叉试验设计,20名健康男性志愿者分2周期分别口服受试制剂和参比制剂各10 mg,HPLC法测定血浆中孟鲁司特钠咀嚼片的浓度,用DAS2.1.1软件计算人体药动学参数并进行生物等效性评价。结果:受试制剂和参比制剂两药的主要药代动力学参数AUC0-t分别为(17.94±6.19)μg h/ml和(17.37±4.73)μg h/ml,AUC0-∞分别为(18.26±6.16)μg h/ml和(17.64±4.66)μg h/ml,Cmax分别为(5.58±1.95)μg/ml和(5.54±1.65)μg/ml,Tmax分别为(2.03±0.97)h和(1.93±0.69)h,t1/2分别为(1.20±0.17)h和(1.19±0.13)h。受试制剂的平均相对生物利用度为(101.5±6.56)%。结论:受试制剂和参比制剂具有生物等效性。     

HPLC-MS/MS法测定人血浆中草乌甲素的浓度及生物等效性研究(英文)

本文建立了一种快速、高灵敏的HPLC-MS/MS法用于检测人血浆中的草乌甲素浓度。血浆样品采用沃特斯HLB小柱进行固相萃取,汉邦C18色谱柱(150 mm×4.6 mm,5μm)进行分离,流动相为甲醇∶水(85∶15,v/v),水相含10 mmol/L的醋酸铵和0.1%的甲酸。采用ESI源和多反应监测(MRM)的方式进行检测,草乌甲素及内标的反应离子对分别为644.4/584.4和237.2/194.2,草乌甲素血药浓度在0.010～1.0 ng/mL范围内线性关系良好,最低定量限为0.010 ng/mL可以满足口服0.4 mg草乌甲素后血药浓度的检测,日内日间及质控样品精密度及准确度均在允许范围内。本检测方法被成功的应用在中国健康志愿者生物等效性研究中,20名志愿者口服0.4 mg草乌甲素试验制剂和参比制剂后主要药代动力学参数分别如下:Cmax(0.325±0.110),(0.323±0.115)ng/mL;AUC0-16(1.627±0.489),(1.732±0.556)ng.h/mL;AUC0-∞(1.730±0.498),(1.831±0.562)ng.h/mL;t1/2(4.26±0.95),(3.80±0.90)h;Tmax(1.34±0.54),(1.83±0.99)h。     

头孢氨苄胶囊制剂人体生物等效性研究

目的:研究新仿制的头孢羟氨苄胶囊制剂与市场在售的同类制剂在健康人体内的生物等效性。方法:采用随机交叉试验设计,20名健康男性志愿者分别口服受试制剂与参比制剂500 mg,HPLC法测定血浆中头孢氨苄的浓度,用DAS 2.0软件计算药动学参数并进行生物等效性评价。结果:受试制剂和参比制剂两药的主要药代动力学参数,Cmax分别为(18.12±3.17)μg/ml和(21.28±3.77)μg/ml,Tmax分别为(1.09±0.37)h和(1.04±0.33)h,t1/2分别为(1.15±0.22)h和(1.14±0.20)h,AUC0-t分别为(35.43±5.39)μg h/ml和(37.27±4.76)μg h/ml,AUC0-∞分别为(36.68±6.06)μg h/ml和(38.62±5.48)μg h/ml,受试制剂的平均相对生物利用度为(96.50±7.2)%。结论:受试制剂和参比制剂具有良好的生物等效性。     

Pharmacokinetics of ciprofloxacin in eels by high-performance liquid chromatography with fluorescence detection

The plasma kinetics of ciprofloxacin (CF) were investigated in the eels after administration by oral gavage and bath treatment. Plasma concentrations of CF were determined by high-performance liquid chromatography with fluorescence detection. The mean concentration time data after oral gavage of a single dose (10.0 mg/kg CF) and after bath treatment by exposure (10 microg/ml CF) to medicated water for 48 h were both best fitted by a one-compartment model. After oral gavage in eels, the half-time of absorption (T1/2Ka) was 0.10 h, the half-time of elimination (T1/2Ke) was 51.87 h, and the maximum plasma concentration (Cmax) was 0.4552 microg/ml at Tmax 0.88 h. After bath treatment, the (T1/2Ka) was 0.02 h, the (T1/2Ke) was 15.46 h, and the Cmax was 0.1175 microg/mL at Tmax 0.22 h.     

High-performance liquid chromatography coupled with electrospray tandem mass spectrometry (LC/MS/MS) method for the simultaneous determination of diazepam, atropine and pralidoxime in human plasma

A high-performance liquid chromatography coupled with electrospray tandem mass spectrometry (LC/MS/MS) procedure for the simultaneous determination of diazepam from avizafone, atropine and pralidoxime in human plasma is described. Sample pretreatment consisted of protein precipitation from 100microl of plasma using acetonitrile containing the internal standard (diazepam D5). Chromatographic separation was performed on a X-Terra MS C8 column (100mmx2.1mm, i.d. 3.5microm), with a quick stepwise gradient using a formate buffer (pH 3, 2mM) and acetonitrile at a flow rate of 0.2ml/min. The triple quadrupole mass spectrometer was operated in positive ion mode and multiple reaction monitoring was used for drug quantification. The method was validated over the concentration ranges of 1-500ng/ml for diazepam, 0.25-50ng/ml for atropine and 5-1000ng/ml for pralidoxime. The coefficients of variation were always <15% for both intra-day and inter-day precision for each analyte. Mean accuracies were also within +/-15%. This method has been successfully applied to a pharmacokinetic study of the three compounds after intramuscular injection of an avizafone-atropine-pralidoxime combination, in healthy subjects.     

Determination of talinolol in human plasma by high performance liquid chromatography-electrospray ionization mass spectrometry: application to pharmacokinetic study

A rapid and sensitive method for determination and screening in human plasma of talinolol is described using propranolol as the internal standard. The analytes in plasma were extracted by liquid-liquid extraction using methyl t-butyl ether. After removed and dried the upper organic phase, the extracts were reconstituted with a fixed volume of buffer of ammonium acetate and acetonitrile (60:40, v/v). The extracts were analyzed by a HPLC coupled to electrospray ionization mass spectrometry (HPLC-MS/ESI). The HPLC separation of the analytes was performed on a Phenomenex C18 (250 mmx4.6 mm, 5 microm, USA) column, with a flow rate of 0.85 mL/min. The complete elution was obtained within 5.5 min. The calibration curve was linear in the 1.0-400.0 ng/mL range for talinolol, with a coefficient of determination of 0.9996. The average extraction recovery was above 83%. The methodology recovery was between 101% and 102%. The limit of detection (LOD) was 0.3 ng/mL for talinolol. The intraday and inter-day coefficients of variation were less than 6%. This HPLC-MS/ESI procedure was used to assess the pharmacokinetics of talinolol. A single oral 50 mg dose of talinolol tablet was administered to 12 healthy Chinese volunteers, the main pharmacokinetic data are as follows: Cmax was 147.8+/-63.8 ng/mL; tmax was 2.0+/-0.7 h; t1/2 was 12.0+/-2.6 h. The method is accurate, sensitive and simple for the pharmacokinetic study of talinolol.     

Pharmacokinetics of an injectable long-acting formulation of doxycycline hyclate in dogs

ABSTRACT: Based on its PK/PD ratios, doxycycline hyclate (DOX-h), a time-dependant antibacterial, is ideally expected to achieve both sustained plasma drug concentrations at or slightly above the MIC level for as long as possible between dosing intervals. Pursuing this end, a poloxamerbased matrix was used to produce a long-acting injectable preparation (DOX-h-LA) and its serum concentrations vs. time profile investigated after its SC injection to dogs ([less than or equal to] 0.3 mL per injection site), and results compared with the oral (PO) and IV pharmacokinetics of DOX-h, prepared as tablet or as freshly made solution. A crossover (4 x 4 x 4) study design was employed with 12 Mongrel dogs, with washout periods of 21 days, and at dose of 10 mg/kg in all cases. DOX-h-LA showed the greatest values for bioavailability (199.48%); maximum serum concentration (Cmax) value was 2.8 +/- 0.3 with a time to reach Cmax (Tmax) of 2.11 +/-0.12 h and an elimination half-life of 133.61 +/- 6.32 h. Considering minimum effective serum concentration of 0.5 mug/mL, a dose-interval of at least 1 week h can be achieved for DOX-hLA, and only 48 h and 24 h after the IV or PO administration of DOX-h as a solution or as tablets, respectively. A non-painful small bulge, apparently non-inflammatory could be distinguished at injection sites. These lumps dissipated completely in 30 days in all cases.