Comparison of in vitro and in vivo release characteristics of acetaminophen from gradient matrix systems

An effort was made to correlate the in vivo and in vitro release data of acetaminophen from two formulations of a recently developed controlled-release system, the Gradient Matrix System (GMS-1 and GMS-2). The in vivo release curves, obtained by deconvolution of the plasma concentration time plots, showed a small inter-subject variability. GMS-1 with fastest in vitro release also showed fastest in vivo release. A good relationship was only found after time-scaling of the release data.     

Pharmacokinetics of dolasetron following single- and multiple-dose intravenous administration to normal male subjects

Dolasetron, Anzemet^TM, a 5-hydroxytryptamine receptor antagonist, is under investigation as an antiemetic agent. The keto-reduced metabolite of dolasetron has been identified in human plasma and is probably responsible for the majority of the antiemetic activity. This study evaluated the pharmacokinetics of dolasetron and the reduced metabolite following single and multiple intravenous (IV) infusions of dolasetron mesylate in healthy male subjects. Four groups of subjects (six active/two placebo) received either dolasetron mesylate or placebo in single IV doses ranging from 0.30 to 0.60 mg kg^?1 on day 1 and multiple IV doses ranging from 0.60 to 1.20 mg kg^?1 d^?1 on days 2–9. Dolasetron could be detected for less than 1 h, while the reduced metabolite appeared rapidly in the plasma, reaching a maximal plasma concentration in less than 1 h. Reduced metabolite maximal plasma concentration was proportional to the dose and the area under plasma concentration curve was linear based on regression analysis. The half-life of reduced metabolite ranged from 3.82 to 7.46 h. The mean renal clearance of reduced metabolite was 2.20–4.43 mL min^?1 kg^?1 and was dose independent. All of the evidence supports dose independent pharmacokinetics for the reduced metabolite. Upon multiple dosing, the reduced metabolite AUC can be predicted from the single-dose pharmacokinetics of this metabolite.     

Pharmacokinetics of flunitrazepam following single- and multiple-dose oral administration to healthy human subjects

Healthy human subjects received single and multiple oral doses of flunitrazepam. Absorption and disposition were first order and reproducible from administration to administration. The oral doses were virtually completely available to the liver, and elimination from the body occurred entirely via metabolism. Assuming the liver to be the sole eliminating organ, hepatic blood clearance and extraction ratio were approximately 0.235 liter/hr/kg and 0.154, respectively. Steady-state blood volume of distribution averaged 3.76 liters/kg in the single-dose studies. Terminal exponential half-lives from the single- and multiple-dose studies (different subjects) averaged 13.5 and 19.2 hr, respectively, these differences were not due to clearance changes but were entirely attributable to variations in volumes of distribution.     

Pharmacokinetics of flunitrazepam following single- and multiple-dose oral administration to healthy human subjects.

Healthy human subjects received single and multiple oral doses of flunitrazepam. Absorption and disposition were first order and reproducible from administration. The oral doses were virtually completely available to the liver, and elimination from the body occurred entirely via metabolism. Assuming the liver to be the sole eliminating organ, hepatic blood clearance and extraction ratio were approximately 0.235 liter/hr/kg and 0.154, respectively. Steady-state blood volume of distribution averaged 3.76 liters/kg in the single-dose studies. Terminal exponential half-lives from the single- and multiple-dose studies (different subjects) averaged 13.5 and 19.2 hr, respectively; these differences were not due to clearance changes but were entirely attributable to variations in volumes of distribution.     

Pharmacokinetics of diazepam following multiple-dose oral administration to healthy human subjects

Six healthy subjects between the ages of 21 and 31 years received diazepam tablets orally at a dose of 5 mg t.i.d. atO, 5, and 10hr on days 1–13. On day 14, the dose was 5 mg at 0 and 5 hr and 15 mg at 10 hr. Subsequently, the dose was 15 mg once daily on days 15–24. Numerous plasma samples were obtained during the multiple-dose regimen, and appropriate equations were fitted to all the multiple-dose data. Diazepam absorption was satisfactorily described by a first-order process, with disposition characterized by a linear two-compartment open model. The harmonic mean absorption half-life was 32 min, and the harmonic mean terminal exponential half-life was 57hr. The mean apparent oral total drug plasma clearance was 22.7ml/hr/kg. Steady-state plasma levels of the primary metabolite, desmethyldiazepam, were reached after 5–8 days of dosing. Steady-state diazepam plasma concentration-time profiles suggested that once daily administration of the total daily dose at bedtime might be a satisfactory dosing regimen.     

Pharmacokinetics of ketotifen after oral administration to healthy male subjects.

The pharmacokinetics of 2 mg ketotifen from four different oral dosage forms were examined in two randomized, balanced cross-over studies. Forty healthy male subjects participated. Each of 20 subjects received two capsule formulations and each of the other 20 subjects received two syrup formulations. Ketotifen concentrations in plasma were determined by a modified GC-MS method. The limit of quantitation was 40 pg ml-1. Inter-day precision and accuracy calculated from quality control samples were 16.3 per cent (-1.9 per cent), 19.8 per cent (+4.5 per cent) and 23.6 per cent (+5.9 per cent) at plasma concentration levels of 86 (n = 18), 215 (n = 19) and 343 (n = 18) pg ml-1, respectively. Ketotifen was rapidly absorbed from all dosage forms reaching Cmax in the order of 400 pg ml-1 after the syrup formulations and 300 pg ml-1 after the capsule formulations within 2 to 4 h. The syrup formulations showed a significantly more rapid rate of absorption as assessed by Tmax. No significant differences in extent of absorption between dosage forms were observed. The terminal elimination half-life of ketotifen varied between subjects from 7 to 27 hours with a mean of about 12 h. The minor pharmacokinetic difference between dosage forms observed in this study is unlikely to be of clinical significance.     

Single-dose and multiple-dose pharmacokinetics and safety of telbivudine after oral administration in healthy Chinese subjects

The pharmacokinetics of telbivudine, an L-nucleoside with potent activity against hepatitis B virus, was assessed in 42 healthy Chinese volunteers. Subjects were assigned to receive a single oral dose of 200, 400, or 800 mg telbivudine or repeat doses of 600 mg/d. Telbivudine was absorbed rapidly and exhibited dose-related plasma exposure. After reaching maximum concentration (C(max)) at a median time of 2.0 to 2.5 hours, plasma disposition of the drug was biphasic with a mean terminal half-life ranging from 39.4 to 49.1 hours. Telbivudine accumulated slightly after repeat doses, and steady state was reached after 5 to 6 consecutive doses of 600 mg/d. The mean steady-state C(max) and area under the plasma concentration-time curve over the dosing interval of telbivudine 600 mg were 3.7 microg/mL and 26.1 microg x h/mL, respectively. Cumulative urinary excretion of telbivudine over 32 hours represented 24.4% of the administered dose, with a mean renal clearance of 6.6 L/h. Telbivudine was well tolerated in the studied dose range in healthy Chinese subjects, with no pattern of dose-related clinical or laboratory adverse events.     

Pharmacokinetics of paracetamol (acetaminophen) after intravenous and oral administration

Summary Plasma paracetamol concentrations were measured in 6 volunteers after single intravenous (1000 mg) and oral (500 mg, 1000 mg and 2000 mg) doses of the drug. Paracetamol levels declined multiphasically with a mean clearance after intravenous administration of 352±40 ml/min. A two-compartment open model appeared to describe the decline adequately. Comparison of the areas under the plasma concentration-time curves (AUC) indicated that oral bioavailability increased from 0.63±0.02 after 500 mg, to 0.89±0.04 and 0.87±0.08 after 1000 mg and 2000 mg, respectively. As a consequence of the incomplete bioavailability of paracetamol, as well as its multicompartmental distribution, accurate estimates of its distribution volume and clearance cannot be obtained if the drug is given orally. However, an estimate of its total plasma clearance may be derived from the AUC after a 500 mg oral dose.     

单剂量口服他达拉非在中国健康男性受试者的药代动力学和安全性

目的 研究中国健康男性受试者单剂量口服他达拉非的药代动力学和安 全性。方法 用双盲随机安慰剂对照三交叉设计。在3个周期随机单次服用 他达拉非10,20 mg或安慰剂,采集静脉血,用液相色谱-质谱法测定血药浓度 并计算药代动力学参数。结果 单次服用他达拉非10,20 mg后的主要药代动 力学参数AUC0-t分别为3750和7180 ng·h·mL-1;AUC0-∞分别为3820和 7370 ng·h·mL-1;Cmax分别为172和274 ng·mL-1;tmax分别为3．00和4．00 h;CL／F分别为2．61和2．71 L·h-1;V／F分别为67．6和73．2 L。结论 他达 拉菲在10-20 mg,中国健康男性受试者较安全,且AUC与剂量呈正相关。     

Absolute bioavailability of imidafenacin after oral administration to healthy subjects

Aims

To investigate the absolute bioavailability of imidafenacin, a new muscarinic receptor antagonist, a single oral dose of 0.1 mg imidafenacin was compared with an intravenous (i.v.) infusion dose of 0.028 mg of the drug in healthy subjects.

Methods

Fourteen healthy male subjects, aged 21–45 years, received a single oral dose of 0.1 mg imidafenacin or an i.v. infusion dose of 0.028 mg imidafenacin over 15 min at two treatment sessions separated by a 1-week wash-out period. Plasma concentrations of imidafenacin and the major metabolites M-2 and imidafenacin-N-glucuronide (N-Glu) were determined. The urinary excretion of imidafenacin was also evaluated. Analytes in biological samples were measured by liquid chromatography tandem mass spectrometry.

Results

The absolute oral bioavailability of imidafenacin was 57.8% (95% confidence interval 54.1, 61.4) with a total clearance of 29.5 ± 6.3 l h⁻¹. The steady-state volume of distribution was 122 ± 28 l, suggesting that imidafenacin distributes to tissues. Renal clearance after i.v. infusion was 3.44 ± 1.08 l h⁻¹, demonstrating that renal clearance plays only a minor role in the elimination of imidafenacin. The ratio of AUC_t of both M-2 and N-Glu to that of imidafenacin was reduced after i.v. infusion from that seen after oral administration, suggesting that M-2 and N-Glu in plasma after oral administration were generated primarily due to first-pass metabolism. No serious adverse events were reported during the study.

Conclusions

The absolute mean oral bioavailability of imidafenacin was determined to be 57.8%. Imidafenacin was well tolerated following both oral administration and i.v. infusion.

What is already known about this subject

• The absolute bioavailability of imidafenacin in rats and dogs is 5.6% and 36.1%, respectively.
• The pharmacokinetic profiles of imidafenacin after oral administration have been revealed.
• Imidafenacin is primarily metabolized to metabolites by CYP3A4 and UGT1A4.

What this study adds

• The absolute bioavailability of imidafenacin in human is 57.8%.
• The pharmacokinetic profiles of imidafenacin after intravenous administration are revealed.
• The formation of metabolites in the plasma is caused mainly by first-pass effects.

     

Pharmacokinetics of PC-SOD, a lecithinized recombinant superoxide dismutase, after single- and multiple-dose administration to healthy Japanese and Caucasian volunteers

To study the pharmacokinetics of single increasing intravenous doses (40-160 mg) and repeated doses (80 mg for 7 days) of lecithinized superoxide dismutase (PC-SOD) in Japanese volunteers and to compare the pharmacokinetics of PC-SOD between Caucasians and Japanese. The Japanese study consisted of 2 parts: a single-dose, open-label, dose-escalation part and a multiple-dose, single-blind, placebo-controlled part. The pharmacokinetics of PC-SOD were determined using noncompartmental and compartmental methods. Pharmacokinetic data from a study with PC-SOD in Caucasians were reanalyzed using the same methodology. The mean (SD) terminal half-life of PC-SOD in Japanese subjects was 25 (4) hours for the 40-mg and 80-mg doses and 31 (15) hours for the 160-mg dose. There was nonlinearity between dose-normalized C(max) and clearance (P values .002 and .022). After multiple dosing, steady state was reached after 5 days. The observed accumulation ratio was 2.6 (0.5). The pharmacokinetics of the single 80-mg dose were similar for Japanese and Caucasians. The pharmacokinetics of PC-SOD was shown to be nonlinear with dose, which may be attributable to a saturable clearing mechanism. The relatively long half-life of PC-SOD (>24 hours) suggests that it is worthwhile to study the compound as a protective agent in clinical conditions with free radical overload.     

Pharmacokinetics of pantoprazole following single intravenous and oral administration to healthy male subjects

Summary The plasma pharmacokinetics of pantoprazole have been investigated following single intravenous infusion and single oral administration at a dose of 40 mg to 12 healthy male subjects in a randomised cross-over study. Both treatments were generally well tolerated and no relevant compound-related adverse events were noted. The plasma pharmacokinetics of pantoprazole following intravenous infusion in this group of subjects were characterised by a total plasma clearance of 0.13 l·h⁻¹·kg⁻¹ and apparent terminal elimination half-life 1.9 h. The apparent volume of distribution estimated at steady state (0.171·kg⁻¹) was compatible with the localization of a major fraction of the compound in extracellular water. Following oral administration as an enteric-coated tablet formulation, a variable onset of absorption was followed by rapid attainment of maximum plasma concentrations of pantoprazole. Pantoprazole was well absorbed following oral administration; the absolute systemic bioavailability of the compound was estimated as 77% (95% CI, 67 to 89%).     

Pharmacokinetic and biopharmaceutic profile of chlordiazepoxide HCl in healthy subjects: Multiple-dose oral administration

Eight healthy male volunteers received chlordiazepoxide HCl orally at a dosage of 10 mg every 8 hr over a period of 21 days. On day 22, the regimen was changed to 30 mg every 24 hr for an additional 15 days. Plasma concentrations of chlordiazepoxide and its metabolites desmethyl-chlordiazepoxide, demoxepam, and desoxydemoxepam were measured during 14 of the 36 treatment days. Chlordiazepoxide plasma concentration- time data were consistent with first-order absorption and complete bioavailability. The harmonic mean absorption half-life was 12.3 min. Disposition of chlordiazepoxide was described by a two-compartment open model with a harmonic mean terminal exponential half-life of 10.1 hr. Average steady — state plasma levels of chlordiazepoxide, desmethylchlordiazepoxide, and demoxepam were approximately 0.75, 0.54, and 0.36 g/ml, respectively.     

Pharmacokinetics of eltoprazine in healthy male subjects after single dose oral and intravenous administration.

The kinetics, safety and tolerability of eltoprazine hydrochloride were studied in an open, cross-over, partially randomised design after single oral (8 mg) and intravenous (3 and 8 mg) doses to 12 healthy male subjects. After intravenous administration, the mean t1/2 ranged from 7 to 9 h, the MRT was 11 h, CL was 487 +/- 148 (3 mg dose) and 471 +/- 56 (8 mg dose) ml kg-1 h-1, while CLR was 226 +/- 124 (3 mg dose) and 189 +/- 38 (8 mg dose) ml kg-1 h-1. The Vss was 3.3 +/- 0.7 (3 mg dose) and 3.8 +/- 0.5 (8 mg dose) 1 kg-1. Cumulative renal excretion was 40%. The AUC and the cumulative urinary excretion were directly proportional to dose within the range of 3-8 mg. Values of tmax varied from 1 to 4 h after oral administration. The mean Cmax value was 24 ng ml-1 after an oral dose of 8 mg. The plasma elimination half-life after oral administration was 9.8 +/- 3.9 h. Absolute oral bioavailability was 110 +/- 32%. Dose-dependent somnolence was observed.     

Apparent absorption kinetics of micronized griseofulvin after its oral administration on single- and multiple-dose regimens to rats as a corn oil-in-water emulsion and aqueous suspension.

This investigation was designed to quantitate and compare in the rat the oral absorption characteristics of micronized griseofulvin from a corn oil-in-water emulsion dosage form containing suspended drug and a control aqueous suspension after single-dose (50 mg/kg) and multiple-dose (50 mg/kg every 12 hr for five doses) administrations. The time course of intact drug in the plasma of all animals was best described by a one-compartment open model with apparent zero-order absorption. In contrast to that observed with the aqueous suspension, the onset of drug absorption after single-dose administration of the corn oil emulsion was significantly delayed. This difference disappeared upon multiple dosing of the two dosage forms, with the mean onset being quite rapid in both cases. Administration of a single dose of the antibiotic as the corn oil emulsion resulted in considerable increases in the maximum plasma levels of griseofulvin and in the duration, relative extent, and uniformity of drug absorption compared to those observed after administration of the control aqueous suspension. The potentiating effects of the lipid on drug absorption persisted on multiple dosing but at a somewhat reduced level.     

Inter- and intrasubject variations of ranitidine pharmacokinetics after oral administration to normal male subjects

Inter- and intrasubject variations of ranitidine pharmacokinetics were examined following oral administration of ranitidine tablets (150 mg as base) under controlled conditions at a timed interval of one week (periods I and II) to 12 healthy male subjects. Significant secondary peaks in the plasma concentration-time curves were observed in all subjects in both periods. The first peak occurred at 0.5 to 2.5 h and the second peak at 3 to 6 h after the dosing. There were great variations in the plasma concentration-time profiles among subjects; for example, the area under the plasma concentration-time curve from time 0 to 12 h (AUC0-12) varied from 1905 to 5672 micrograms.h/mL. But bioavailability parameters of period I, such as maximum concentration of the first and second plasma peak (Cmax 1 and Cmax 2, respectively), time to first peak (tmax 1), AUC0-12, and AUC from time zero to infinity (AUC0-infinity), were correlated significantly with those of period II. These results suggest that the intrasubject variation of ranitidine pharmacokinetics is usually small over at least one week under the controlled conditions of this study, in spite of its great intersubject variation.     

Disposition,elimination, and metabolism of tri-o-cresyl phosphate following daily oral administration in Fischer 344 male rats

The disposition, elimination, and metabolism of 50 mg/kg (1.36 Ci/animal) of tri-o-cresyl [phenyl-U-¹⁴C] phosphate after ten daily oral doses was investigated in adult male Fischer 344 rats. Groups of three treated animals were killed at intervals of 24, 48, 72, and 96 h after the last administrations. Generally, the highest concentrations of radioactive material were excreted via the gastrointestinal tract and the bladder, particularly at the earlier time points. Liver, adipose, epididymis, sciatic nerve tissues; plasma; and red blood cells also contained high concentrations of radioactivity. The lowest concentrations were found in brain, spleen, testes, and heart. Four days after the last dose, the rats had excreted approximately all of the cumulative dose in either urine (63.1%) or feces (36.1%). TOCP and its metabolites in urine, feces, plasma, brain, testes, kidneys, and liver were analyzed by high-performance liquid chromatography and liquid scintillation. Metabolism studies performed 24, 48, 72, and 96 h after administration of the last dose showed that TOCP was the major compound identified in brain, testes, kidneys, plasma, and liver. Liver, additionally, had high levels of di-o-cresyl hydrogen phosphate ando-cresol. TOCP ando-cresol were the predominant compounds in feces; only trace amounts of TOCP were detected in urine. The major metabolites in urine were di-o-cresyl hydrogen phosphate,o-cresol, ando-hydroxy benzoic acid. Testes in rats given ten doses had significantly more TOCP and saligenin cyclic-o-tolyl phosphate than those from rats given a single dose. These results may account for testicular toxicity in rats given daily oral administrations of TOCP but not following a single oral dose.     

Comparative pharmacokinetics of midazolam and loprazolam in healthy subjects after oral administration

The pharmacokinetics of oral midazolam (Dormicum, 15 mg) and loprazolam (Dormonoct, 1 mg) were studied in eight healthy young volunteers in a cross-over design. Plasma concentrations of midazolam were measured with a gas chromatographic method and loprazolam concentrations were determined by a radio-receptor technique. Absorption of midazolam proceeded very rapidly (median tmax = 0.4 h) and a rapid onset of sedative action was observed. Loprazolam absorption was relatively slow (median tmax = 3 h) and its absorption profile was often irregular. Most subjects fell asleep before peak concentrations were reached. Median peak concentrations were 94 ng ml-1 and 3.1 ng ml-1 for midazolam and loprozolam, respectively. The median elimination half-life of midazolam was 1.8 h and that of loprazolam 15 h. It is possible that the elimination half-life of loprazolam as determined by radioreceptor assay is determined by active metabolites rather than by loprazolam itself. Midazolam elimination half-life was the same when determined by radioreceptor assay or by GLC. There was no significant correlation between the half-lives of the two drugs.     

Safety, tolerability, and pharmacokinetics of PTC124, a nonaminoglycoside nonsense mutation suppressor, following single- and multiple-dose administration to healthy male and female adult volunteers

Nonsense (premature stop codon) mutations are causative in 5% to 15% of patients with monogenetic inherited disorders. PTC124, a 284-Dalton 1,2,4-oxadiazole, promotes ribosomal readthrough of premature stop codons in mRNA and offers therapeutic potential for multiple genetic diseases. The authors conducted 2 phase I studies of PTC124 in 62 healthy adult volunteers. The initial, single-dose study evaluated doses of 3 to 200 mg/kg and assessed fed-fasting status on pharmacokinetics following a dose of 50 mg/kg. The subsequent multiple-dose study evaluated doses from 10 to 50 mg/kg/dose twice per day (bid) for up to 14 days. PTC124 administered orally as a liquid suspension was palatable and well tolerated through single doses of 100 mg/kg. At 150 and 200 mg/kg, PTC124 induced mild headache, dizziness, and gastrointestinal events. With repeated doses through 50 mg/kg/dose bid, reversible transaminase elevations <2 times the upper limit of normal were sometimes observed. Immunoblot analyses of peripheral blood mononuclear cell extracts revealed no protein elongation due to nonspecific ribosomal readthrough of normal stop codons. PTC124 plasma concentrations exceeding the 2- to 10-microg/mL values associated with activity in preclinical genetic disease models were safely achieved. No sex-related differences in pharmacokinetics were seen. No drug accumulation with repeated dosing was apparent. Diurnal variation was observed, with greater PTC124 exposures after evening doses. PTC124 excretion in the urine was <2%. PTC124 pharmacokinetics were described by a 1-compartment model. Collectively, the data support initiation of phase II studies of PTC124 in patients with nonsense mutation-mediated cystic fibrosis and Duchenne muscular dystrophy.     

The pharmacokinetics and metabolism of oxycodone after intramuscular and oral administration to healthy subjects.

1. The pharmacokinetics and metabolism of oxycodone were studied in nine healthy young volunteers in a cross-over study. Each subject received oxycodone chloride once intramuscularly (0.14 mg kg-1) and twice orally (0.28 mg kg-1) at intervals of 2 weeks. A double-blind randomized pretreatment with amitriptyline (10-50 mg a day) or placebo was given prior to oral oxycodone. 2. The concentrations of oxycodone, noroxycodone and oxymorphone in plasma and the 24 h urine recoveries of their conjugated and unconjugated forms were measured by gas chromatography. 3. No differences were found between treatments in mean Cmax and AUC values of oxycodone which varied from 34 to 38 ng ml-1 and from 208 to 245 ng ml-1 h, respectively. The median tmax of oxycodone was 1 h in all groups. The bioavailability of oral relative to i.m. oxycodone was 60%. The mean renal clearance of oxycodone was 0.07-0.08 l min-1. The kinetics of oxycodone were unaffected by amitriptyline. 4. The mean ratio of the AUC(0.24 h) values of unconjugated noroxycodone to oxycodone was 0.45 after i.m. oxycodone and 0.6-0.8 after oral oxycodone. Plasma oxymorphone concentrations were below the limit of the assay. Eight to 14% of the dose of oxycodone was excreted in the urine as unconjugated and conjugated oxycodone over 24 h. Oxymorphone was excreted mainly as a conjugate whereas noroxycodone was recovered mostly in an unconjugated form.