Tolerance and pharmacokinetics of single-dose atorvastatin, a potent inhibitor of HMG-CoA reductase, in healthy subjects

Tolerance and pharmacokinetics after single-dose administration of atorvastatin, an investigational inhibitor of HMG-CoA reductase, were examined in 22 healthy volunteers in a three-period, partially-blinded study. Participants received capsule and solution doses of atorvastatin (0.5 to 120 mg) and placebo at weekly intervals. Atorvastatin was well tolerated at doses as high as 80 mg. The adverse event profile was similar after administration of atorvastatin capsules and placebo. Atorvastatin solution was slightly less well tolerated. The most common side effect after administration of capsules and solution was headache, followed by sporadic reports of diarrhea, flatulence, and nausea. At the 120-mg solution dose, one participant experienced mild, transient restlessness, euphoria, and mental confusion that were considered to be dose-limiting side effects. Mean concentrations of atorvastatin, maximum concentration (Cmax), and area under the concentration-time curve from time 0 to the time of the last detectable concentration (AUCo-tldc) increased with increasing dose. Plasma elimination half-life (t1/2) ranged from 14.7 to 57.6 hours. The bioavailability of atorvastatin capsules was similar to that of solution. These results suggest that atorvastatin is well tolerated after single doses as high as 80 mg, and may require administration only once daily.     

Pharmacokinetics and safety of oral levofloxacin in human immunodeficiency virus-infected individuals receiving concomitant zidovudine

This phase I, double-blind, randomized, placebo-controlled, parallel-design study was conducted to evaluate the safety and pharmacokinetics of levofloxacin in human immunodeficiency virus (HIV)-infected subjects concomitantly receiving a stable regimen of zidovudine (AZT). Sixteen HIV-infected males with CD4-cell counts ranging from 100 to 550 and not experiencing significant AZT intolerance were enrolled. Subjects received levofloxacin (350 mg of levofloxacin hemihydrate) or a placebo (eight subjects per treatment group) as a single oral dose on day 1, multiple doses every 8 h from days 3 to 9, and a single dose on day 10. On days 1 and 10, an AZT dose (100 mg) was administered concurrently with the study drug. In between these doses, AZT was administered according to the regimen used by the subject prior to entering the study up to a maximum of 500 mg/day. Plasma levofloxacin concentrations were monitored for 36 h after levofloxacin dosing on day 1, immediately prior to the morning doses on days 3 to 9, and for 72 h after dosing on day 10. Plasma AZT concentrations were monitored on day 0 for baseline (for 6 h after the AZT dose) and for 4 h after the AZT doses on days 1 and 10. Levofloxacin was rapidly absorbed (time to maximum plasma concentration, approximately 1.0 h) and extensively distributed in the body with an apparent volume of distribution of approximately 104 liters (approximately 1.34 liters/kg). Steady-state conditions on day 10 were confirmed. Pharmacokinetic profiles of levofloxacin from single doses and multiple (three-times-daily) doses were similar, with a moderate accumulation (observed day 10-to-day 1 ratio of the maximum plasma concentration, approximately 185% versus expected 169%; for the corresponding ratio of the area under the concentration-time curve from 0 to 8 h [AUC(0-8)], the values were observed 217% versus expected 169%) at steady state. Mean average steady-state peak plasma concentration, plasma levofloxacin concentration at the end of the dosing interval, AUC(0-8), terminal half-life, and total body clearance were 7.06 microg/ml, 3.62 microg/ml, 37.4 microg x h/ml, 7.2 h, and 9.4 liters/h (0.12 liters/h/kg), respectively. Pharmacokinetic profiles of levofloxacin in HIV-infected patients did not appear to be affected by the concomitant administration of AZT; nor were AZT pharmacokinetics altered by levofloxacin. Oral administration of 350 mg of levofloxacin hemihydrate every 8 h appeared to be well tolerated by the subjects. There were no apparent differences in adverse events between the two treatment groups. There were no clinically significant changes from baseline in any laboratory parameter or vital sign following treatments observed in this study. The study results suggest that there is no need for levofloxacin dosage adjustment in HIV-seropositive subjects who concomitantly receive AZT.     

Localization of putative elements of 5''-region of human tyrosine aminotransferase gene mediating its expression by glucocorticoids

The purpose of this study was to determine the pharmacokinetics and absolute bioavailability of cisapride after intravenous (i.v.) and intragastric (i.g.) administration in healthy, adult horses. Five animals received single doses of 0.1 mg/kg, 0.2 mg/kg and 0.4 mg/kg cisapride by the i.g. route in an open, randomized fashion on different occasions separated by a washout period of at least 48 h. Four of these horses were also given a single i.v. dose of 0.1 mg/kg cisapride. Jugular venous blood was collected periodically up to 24 h after dosing. Plasma cisapride concentrations were measured by high-performance liquid chromatography. There was considerable inter individual variability in pharmacokinetic parameters. The mean (SD) values for systemic clearance (CI) and steady-state volume of distribution (Vss) were 494 (43.6) mL/h/kg and 1471 (578) mL/kg, respectively. Although the rate of cisapride absorption was quite rapid, only about half the i.g. dose was absorbed systemically. The average terminal half-life (t1/2) calculated over three i.g. doses was 2.06 h and that for i.v. administration was 2.12 h. The pharmacokinetics of cisapride from 0.1 mg/kg to 0.4 mg/kg were independent of the i.g. dose.     

Pharmacokinetics of methylprednisolone and prednisolone after single and multiple oral administration

The pharmacokinetics of methylprednisolone and prednisolone were evaluated in 24 healthy men after oral administration of single and multiple doses for 3 days. For each drug, 6 different administration regimens with doses ranging from 1 to 80-mg of methylprednisolone and 1.25 to 100-mg of prednisolone, and administration intervals ranging from 3 to 24 hours for both were investigated. Plasma was assayed using a normal phase high-performance liquid chromatography (HPLC) method. Methylprednisolone showed linear pharmacokinetics with no apparent dose or time dependency. Prednisolone showed marked dose dependency with higher clearance and volume of distribution for higher doses. This can be explained by its saturable protein binding of plasma, because unbound clearance and unbound volume of distribution were not dose-dependent. After multiple administration, prednisolone showed significant time-dependent pharmacokinetics with increased unbound clearance and increased unbound volume of distribution. Due to the complicated pharmacokinetic properties of prednisolone, it is extremely difficult to determine the dose needed to obtain a desired target concentration. The pharmacokinetics of methylprednisolone are more predictable because methylprednisolone concentrations are proportional to dose, and no determination of plasma protein binding is needed.     

Phase I clinical and pharmacokinetic study of titanocene dichloride in adults with advanced solid tumors

This Phase I dose-escalation clinical trial of a lyophilized formulation of titanocene dichloride (MKT4) was conducted to determine the maximum tolerated dose, the dose-limiting toxicity (DLT), and pharmacokinetics of titanium (Ti) after a single i.v. infusion of MKT4. Forty patients with refractory solid malignancies were treated with a total of 78 courses. Using a modified Fibonacci scheme, 15 mg/m2 initial doses of titanocene dichloride were increased in cohorts of three patients up to level 11 (560 mg/m2) if DLT was not observed. The maximum tolerated dose was 315 mg/m2, and nephrotoxicity was DLT. Two minor responses (bladder carcinoma and non-small cell lung cancer) were observed. The pharmacokinetics of plasma Ti were assessed in 14 treatment courses by atomic absorption spectroscopy. The ratio for the area under the curve(0-infinity) in plasma and whole blood was 1.2. The following pharmacokinetic parameters were determined for plasma, as calculated in a two-compartment model: biological half-life t1/2beta in plasma was 22.8+/-11.2 h (xh +/- pseudo-SD), peak plasma concentration cmax approximately 30 microg/ml at a dose of 420 mg/m2, distribution volume Vss= 5.34+/-2.1 L (xa +/- SD), and a total clearance CItotal = 2.58+/-1.23 ml/min (xa +/- SD). There was a linear correlation between the area under the curve(0-infinity) of Ti in plasma and the titanocene dichloride dose administered with a correlation coefficient r2 of 0.8856. Plasma protein binding of Ti was in the 70-80% range. Between 3% and 16% of the total amount of Ti administered were renally excreted during the first 36 h. The recommended dose for Phase II evaluation is 240 mg/m2 given every 3 weeks with i.v. hydration to reduce renal toxicity.     

Pharmacokinetics of heparin and its pharmacodynamic effect on plasma lipoprotein lipase activity and coagulation in healthy horses

We evaluated the pharmacokinetics of IV administered sodium heparin and the pharmacodynamic effect of heparin on lipoprotein lipase (LPL) activity. Horses were allotted to 3 groups. Plasma samples were obtained from each horse before and at various times for 6 hours after heparin administration for determination of heparin concentration, LPL activity, and activated partial thromboplastin time (APTT). The disposition of heparin was dose dependent. The area under the plasma heparin concentration vs time curve (AUC) increased more than proportionally with dose, indicating that heparin elimination was nonlinear. Total clearance of heparin was similar after the 40 and 80 IU/kg of body weight dosages, averaging 0.45 and 0.36 IU/kg/min, respectively. However, after administration of the 120 IU/kg dose, clearance was significantly less than that after the 40 IU/kg dose. The half-life of heparin averaged 53, 70, and 136 minutes after 40, 80, and 120 IU/kg, respectively, with significant differences observed between the low and high doses. In contrast to heparin, the area under the plasma concentration vs time curve for LPL activity increased less than proportionally with dose. Maximal LPL activity observed was independent of dose, averaging 4.8 mumol of free fatty acids/ml/h. The APTT was significantly prolonged for 120 minutes after administration of the 40 IU/kg dose. Correlation coefficients for LPL activity vs either plasma heparin concentration or APTT were less than 0.7, indicating that neither laboratory measure can be used to accurately predict plasma LPL activity.     

Pharmacokinetics of VP16-213 in Lewis lung carcinoma bearing mice

The pharmacokinetics of VP16 have been investigated in Lewis lung bearing mice after i.v. doses of 13 and 40 mg/kg. At both doses the plasma elimination of half-life was around 30 min. The lowest VP16-213 levels were in brain and primary tumor. Drug concentrations were much higher in metastases than in primary tumor. The highest concentrations were in small intestine, liver and kidney. Drug levels in the liver were disproportionally higher after 40 mg/kg, and AUC value being approximately 12 times greater than after 13 mg/kg. Urinary excretion of VP16-213 as unchanged drug accounted for 20-30% of the administrated dose in the 60 h after treatment. The concentration cytotoxicity curve was very steep and apparently similar for cells derived from primary tumor or metastases grown in vitro.     

Should benefit-risk ratio of the intramuscular vitamin K be reevaluated in newborn infants?

AIM: To compare the pharmacokinetics after po different doses of beta-carboxyethylgermanium sesquioxide (Ge-132). METHODS: An atomic absorption spectrophotometric system was used to measure germanium concentrations in plasma and urine samples after po Ge-132 1 (low dose, LD), 2.5 (medium dose, MD), and 4 (high dose, HD) g.m-2 in 24 healthy volunteers (one dose per 8 subjects). RESULTS: T1/2 alpha (LD, 1.2 +/- 0.7 h; MD, 1.1 +/- 0.6 h; HD, 1.2 +/- 0.5 h), T1/2 beta (LD, 5.2 +/- 1.2 h; MD, 5.8 +/- 2.5 h; HD, 5.5 +/- 1.4 h) and Cl/F (LD, 33 +/- 12 L.h-1; MD, 35 +/- 10 L.h-1; HD, 33 +/- 11 L.h-1) were not dose-related. Tmax was between 0.75 h and 2 h. Cmax (LD, 5.3 +/- 2.2 mg.L-1; MD, 13 +/- 5 mg.L-1; HD 18 +/- 8 mg.L-1, HD) and AUC (LD, 31 +/- 13 mg.h.L-1; MD, 60 +/- 16 mg.h.L-1; HD, 79 +/- 42 mg.h.L-1) were positive correlation to the dose of Ge-132. Urine-eliminated germanium within 24 h accounted for 11 +/- 3% of LD, 9 +/- 3% of MD, and 6 +/- 5% of HD (calculated from Ge/F) and showed a negative correlation to the dose. CONCLUSION: 1) Intracorporal process of Ge after po Ge-132 coincided with the first-order absorption and elimination with two-compartment kinetic model; 2) The amount of germanium eliminated in urine was below 11%.     

MMSP tumor cells expressing the EWS/ATF1 oncogene do not support cAMP-inducible transcription

OBJECTIVE: The therapeutic effects of methylphenidate in the treatment of attention deficit disorder have been attributed to its ability to increase the synaptic concentration of dopamine by blocking the dopamine transporters. However, the levels of dopamine transporter blockade achieved by therapeutic doses of methylphenidate are not known. This study measured, for the first time, dopamine transporter occupancy by orally administered methylphenidate in the human brain and its rate of uptake in the brain. METHOD: Positron emission tomography (PET) and [11C]cocaine were used to estimate dopamine transporter occupancies after different doses of oral methylphenidate in seven normal subjects (mean age=24 years, SD=7). In addition, the pharmacokinetics of oral methylphenidate were measured in the baboon brain through use of PET and [11C]methylphenidate administered through an orogastric tube. RESULTS: At 120 minutes after administration, oral methylphenidate produced a dose-dependent blockade of dopamine transporter; means=12% (SD= 4%) for 5 mg, 40% (SD=12%) for 10 mg, 54% (SD=5%) for 20 mg, 72% (SD=3%) for 40 mg, and 74% (SD=2%) for 60 mg. The estimated dose of oral methylphenidate required to block 50% of the dopamine transporter corresponded to 0.25 mg/kg. Oral methylphenidate did not reach peak concentration in brain until 60 minutes after its administration. CONCLUSIONS: Oral methylphenidate is very effective in blocking dopamine transporters, and at the weight-adjusted doses used therapeutically (0.3 to 0.6 mg/kg), it is likely to occupy more than 50% of the dopamine transporters. The time to reach peak brain uptake for oral methylphenidate in brain corresponds well with the reported time course to reach peak behavioral effects.     

Pharmacokinetics and tolerance of pantoprazole, a proton pump inhibitor after single and multiple oral doses in healthy Japanese volunteers

The pharmacokinetics and tolerance of pantoprazole were investigated after single (20, 40, 80, and 120 mg) and multiple (80 mg once a day for 7 days) oral administration as enteric-coated tablet formulation to healthy male Japanese volunteers. Pantoprazole was well tolerated with no serious adverse events at all doses. Pantoprazole was rapidly absorbed in the fasted state. The mean maximum concentration in serum (Cmax) ranged from 1.77-9.25 micrograms/ml for the 20-120 mg dose and the mean time to reach Cmax (tmax) ranged from 1.92-2.42 h. The half-life (t1/2) ranged from 0.74-1.16 h. A good linear correlation was found between the administered doses (20-120 mg) and the resulting area under the concentration-time curve (AUC) and Cmax with the correlation coefficients of 0.9088 and 0.9263, respectively. Within 24 h, pantoprazole was excreted into urine as the unchanged drug to a negligible extent. In the multiple dose study, 2 apparent poor metabolizers (PMs) of pantoprazole were observed. The means of Cmax, AUC and t1/2 for these 2 PMs were 1.6, 6.7, and 6.8 times higher than those of the extensive metabolizers (EMs). The pharmacokinetic parameters such as Cmax, AUC, and t1/2 after the 7th oral dose were not significantly different from those after the 1st dose both in the PMs and the EMs, which indicated that there was virtually no drug accumulation.     

Pharmacokinetics of and CYP1A induction by pyridine and acetone in the rat: interactions and effects of route of exposure

1. Male Sprague-Dawley rats were exposed to either pyridine, acetone or a combination of both compounds by either intraperitoneal administration (100 mg/kg pyridine or 400 mg/kg acetone) or whole-body inhalation (200 ppm pyridine or 1000 ppm acetone). Plasma and tissue levels of both compounds were determined by gas chromatography/mass spectrometry. 2. Both chemicals were well distributed in the tissues examined following either route of exposure, with concentrations in the order kidney > liver > plasma > lung. 3. Plasma half-life of pyridine was 7 h following a single 100 mg/kg dose of the compound, and 8 h following the last dose of a 3-day, 8 h/day exposure to a 200 ppm inhalation dose of the compound. 4. Plasma half-life of acetone was 4 h and was independent of the route of exposure. 5. The pharmacokinetics of pyridine was not affected by co-exposure to acetone. Similarly, the pharmacokinetics of acetone was not affected by co-exposure to pyridine. 6. Ethoxyresorufin O-deethylase activity in lung and liver and methoxyresorufin O-demethylase activities in liver were induced by pyridine but not by acetone at the doses examined. Pyridine-induced ethoxyresorufin O-deethylase activity was higher following inhalation exposure than following i.p. administration of pyridine but did not parallel tissue levels of the compound.     

Modulation of renal kallikrein production by dietary protein in streptozotocin-induced diabetic rats

Renal kallikrein levels and excretion rates are increased in insulin-treated diabetic rats with hyperfiltration, and inhibition of kallikrein or blockade of kinin receptors reduces GFR and RPF. In contrast, insulin-deprived severely (SD) diabetic rats that display renal vasoconstriction show reduced levels and excretion rates of renal kallikrein. In these two models, dietary protein manipulation was utilized to study further the relationships between renal kallikrein and renal hemodynamic regulation. Insulin-deprived SD and insulin-treated moderately diabetic (MD) rats were fed a low (9%), normal (25%), and a high (50%) protein diet. In SD rats fed the 50% protein diet, GFR, RPF, and kallikrein excretion rate were increased compared with SD rats fed the 25% protein diet (GFR, 2.66 +/- 0.16 versus 1.74 +/- 0.30 mL/min; RPF, 7.78 +/- 0.58 versus 5.14 +/- 1.03 mL/min; total kallikrein, 248 +/- 24 versus 120 +/- 30 micrograms/24 h, SD 50% versus SD 25%, respectively; P < 0.005). In MD rats fed the 9% protein diet, GFR, RPF, and kallikrein excretion rate were significantly reduced compared with MD 25% protein-fed rats (GFR, 1.54 +/- 0.07 versus 1.95 +/- 0.09 mL/min; RPF, 5.58 +/- 0.35 versus 7.81 +/- 0.35 mL/min; total kallikrein, 119 +/- 8.3 versus 219 +/- 15 micrograms/24 h, MD 9% versus MD 25%, respectively; P < 0.005). Protein restriction in normal nondiabetic rats resulted in a twofold decrease in kallikrein mRNA levels. These findings suggest that the renal hemodynamic response to dietary protein manipulation in diabetic rats could be mediated via changes in renal kallikrein-kinin system activity.     

Phase I clinical and pharmacological studies of benzylacyclouridine, a uridine phosphorylase inhibitor

Benzylacyclouridine (BAU, IND 039655) is a potent and specific inhibitor of uridine phosphorylase (UrdPase; EC 2.4.2.3). This enzyme plays a major role in regulating uridine homeostasis and also catalyzes the conversion of fluoropyrimidine nucleosides to their respective bases. Inhibition of UrdPase enzyme activity 18-24 h after 5-fluorouracil (5-FU) administration increased plasma levels of uridine and enhanced the therapeutic index of 5-FU by rescuing normal tissues. Moreover, in vitro preclinical studies have also shown that inhibiting UrdPase enzyme activity by BAU prior to administration of 5-FU increased cytotoxicity in a number of human cancer cell lines. A series of preclinical studies was performed in dogs and pigs to evaluate the pharmacological and pharmacodynamic properties of BAU. These data showed a sustained elevation in plasma uridine concentration in both animal models. The rapid degradation of a tracer dose of uridine into uracil was virtually arrested by BAU administered both p.o. or i.v. The t1/2 of BAU was 1.8-3.6 h in dogs, with bioavailability levels of 85% (30 mg/kg) and 42.5% (120 mg/kg). In pigs, the half-life varied from 1.6 to 2.3 h, with a bioavailability of 40% at 120 mg/kg. The drug was distributed into most tissues with a tissue: plasma ratio of approximately 0.7. On the basis of these preclinical studies, we performed a Phase I clinical trial of BAU in patients with advanced cancer. Patients received 200, 400, 800, and 1600 mg/m2 BAU as a single oral dose. Toxicities included grade 2 anemia, grade 1 fever, grade 1 fatigue, grade 1 constipation, and grade 1 elevation in alkaline phosphatase; none of these toxicities were observed to be dose dependent. The maximum tolerated dose and dose-limiting toxicity were not reached at the doses given. BAU plasma concentrations and area under the curve correlated linearly with the oral dose level. The pharmacokinetics of BAU were consistent with a first-order clearance, with average peak concentrations ranging from 19 microM (200 mg/m2) to 99 microM (1600 mg/m2) and tbeta1/2 ranging from 3.0 to 3.9 h at the four dose levels. Compared with baseline plasma uridine, treatment of patients with 200, 400, 800, and 1600 mg/m2 BAU increased peak uridine concentrations by 120, 150, 250, and 175%, respectively. On the basis of this clinical study, the suggested Phase II starting dose of BAU in combination with 5-FU is 800 mg/m2. Studies combining BAU with 5-FU and incorporating appropriate molecular and biochemical end points to assess the effects of this drug combination on tumor and/or surrogate tumor tissue are under way.     

Tau protein. A potential biological indicator for early detection of Alzheimer disease]

C1311 is the most active member of a new series of rationally designed anti-cancer agents, the imidazoacridinones, which has shown promising pre-clinical anti-tumour activity in vitro and in vivo against a variety of human colon cancers and is a strong candidate for clinical trials. Data are not available on the pharmacokinetic properties of this compound; therefore, the main aim of this project was to study the plasma pharmacokinetics and tissue and tumour distribution of C1311 in mice and to assess, prior to potential clinical application, whether these pharmacokinetics were linear with respect to the dose. The distribution of C1311 in whole blood was also studied. NMRI or NCR-Nu mice were used throughout the study. C1311 was given i.p. at doses of 15, 50, 100 and (the maximum tolerated dose, (MTD) 150 mg kg(-l) i.p. Plasma, tissue and tumour levels were monitored over a 24-h period using high-performance liquid chromatography (HPLC) with fluorescence detection. The distribution of C1311 in murine and human whole blood was studied using both HPLC and fluorescence microscopy. C1311 was quickly cleared from the plasma (47410 ml min kg(-1)) and rapidly distributed into the tissues at all doses. Tissue-to-plasma ratios were large, ranging from 8 in the liver (15 mg kg(-l)) to 600 (50 mg kg(-1)) in the spleen. Overall concentrations were ranked in the order of plasma < liver < kidney < fat < small intestine < spleen. Tumour concentrations were similar to those measured in the liver and kidney, with AUCs being 186 (MAC15A) and 94.4 microg h ml(-l)(HT-29). Plasma pharmacokinetics were linear at doses of 15-100 mg kg(-1), but disproportionate increases were seen in plasma and tissue concentrations at doses above 100 mg kg(-l). C1311 distributed unevenly in both mouse and human blood, with higher concentrations occurring in the cellular fraction than in plasma. Nucleated cells accounted for a large proportion of this localised drug. In conclusion, C1311 is quickly cleared from the plasma and rapidly distributed into the tissues, with tissue concentrations being far higher than plasma levels. The plasma pharmacokinetics are linear up to but not above doses of 100 mg kg(-1). Concentrations of C1311 are greater in the cellular fraction of the blood than in the plasma, with disproportionately high concentrations occurring in the nucleated fraction.     

Pharmacokinetics of gentamicin at traditional versus high doses: implications for once-daily aminoglycoside dosing

Two doses of gentamicin (2 and 7 mg/kg of body weight) were administered to 11 healthy volunteers in a randomized, crossover single-dose study to compare their pharmacokinetics. Doses were infused over 1 h with a syringe infusion pump, and 14 concentrations in sera were obtained over an 8-h period. Concentration in serum versus time data were fitted to a two-compartment pharmacokinetic model. In addition, to mimic the clinical setting, subjects' data were fitted by the Sawchuk-Zaske method. Distributional and postdistributional peak concentrations, along with the last obtained concentration in serum, were utilized to compare the following pharmacokinetic variables: volume of distribution at steady state (Vss), half-life, clearance (CL), and maximum concentration in serum (Cmax). With two-compartment pharmacokinetic fitting, significant differences in distribution half-life (average, 21.8 and 41.6 min [P < or = 0.05]) and gentamicin CL (76.6 +/- 6.6 and 67.2 +/- 4.2 ml/min/1.73 m2 [P < or = 0.001]) were found between traditional-dose and high-dose groups, respectively. When the data for concentrations in sera were fitted to a one-compartment pharmacokinetic model by using either the distributional or the postdistributional Cmax, statistically significant differences (P < or = 0.001) were found between Vss, half-life, CL, and Cmax values for both dosage groups. The results show that the pharmacokinetics of gentamicin at a large dose differ significantly from those at the traditional dose. This information has direct implications for once-daily aminoglycoside (ODA) literature when the Cmax values reported are distributional and therefore show falsely high Cmax/MIC ratio estimates. In addition, ODA nomogram dosing tools developed with distributional Cmax values are probably inaccurate.     

Dose proportionality and comparison of single and multiple dose pharmacokinetics of fexofenadine (MDL 16455) and its enantiomers in healthy male volunteers

The pharmacokinetics and dose proportionality of fexofenadine, a new non-sedating antihistamine, and its enantiomers were characterized after single and multiple-dose administration of its hydrochloride salt. A total of 24 healthy male volunteers (31 +/- 8 years) received oral doses of 20, 60, 120 and 240 mg fexofenadine HCl in a randomized, complete four-period cross-over design. Subjects received a single oral dose on day 1, and multiple oral doses every 12 h on day 3 through the morning on day 7. Treatments were separated by a 14-day washout period. Serial blood and urine samples were collected for up to 48 h following the first and last doses of fexofenadine HCl. Fexofenadine and its R(+) and S(-) enantiomers were analysed in plasma and urine by validated HPLC methods. Fexofenadine pharmacokinetics were linear across the 20-120 mg dose range, but a small disproportionate increase in area under the plasma concentration-time curve (AUC) (< 25%) was observed following the 240 mg dose. Single-dose pharmacokinetics of fexofenadine were predictive of steady-state pharmacokinetics. Urinary elimination of fexofenadine played a minor role (10%) in the disposition of this drug. A 63:37 steady-state ratio of R(+) and S(-) fexofenadine was observed in plasma. This ratio was essentially constant across time and dose. R(+) and S(-) fexofenadine were eliminated into urine in equal rates and quantities. All doses of fexofenadine HCl were well tolerated after single and multiple-dose administration.     

Increasing plasma concentration tolerability study of flunarizine in comedicated epileptic patients

Twelve patients with intractable partial seizures [4 receiving carbamazepine (CBZ), 4 phenytoin (PHT), and 4 both] entered a study of the tolerability of flunarizine (FNR) at specified plasma concentrations. After an 8-week baseline period, a single-dose pharmacokinetic study was performed for each patient to calculate a loading dose and maintenance dosage necessary to achieve a target plasma FNR concentration of 30 ng/ml. The first 8 patients received the loading dose (as divided doses) during a 1-week hospitalization and the maintenance dosage for the ensuing 8 weeks. These patients proceeded to treatment periods with target concentrations of 60 and then 120 ng/ml, using doses based on an assumed linear relation between dose and plasma concentration. The last 4 patients were studied only at the 120- ng/ml target level. Results indicated that this procedure successfully approximated target levels of 30 and 60 ng/ml, but observed concentrations in the last period exceeded the 120-ng/ml target level and continued to increase with time, often necessitating a dosage reduction owing to intolerability. Calculated doses for a given target concentration varied by a factor of 12. The most frequently reported adverse experiences were sedation and increased fatigue; reports of dizziness, headache, and lethargy were also common. Based on this study, a target concentration of at least 60 but < 120 ng/ml is recommended for a controlled clinical trial of the antiepileptic efficacy of FNR.     

Correlation between the pharmacokinetics of oxindanac and inhibition of serum thromboxane B2 in calves

The pharmacokinetics and pharmacodynamics of the non-steroidal antiinflammatory drug, oxindanac, were assessed simultaneously in calves after intravenous (i.v.) administration at dose rates of 0.5, 1, 2, 4 and 8 mg/kg. Plasma pharmacokinetic data were fitted to either two or three compartment open models. The elimination t1/2 was constant in the dose range 0.5 to 4 mg/kg (20.2-22.8 h) and shorter at 8 mg/kg (14.7 h). The pharmacodynamics of oxindanac were assessed by its inhibition of serum TxB2, an index of platelet cyclo-oxygenase activity. Plots of total plasma oxindanac concentration vs. inhibition of serum TxB2 fitted in all cases a sigmoidal Emax equation. There were no significant differences in the estimates for ED50 (1.6-1.9 micrograms/ml), Hill constant (1.3-2.7) or Emax between the doses used in the in vivo studies or when blood was spiked with oxindanac in vitro. Plots of inhibition of serum TxB2 vs. time were prepared from the pharmacokinetic model equations in each calf in combination with a single sigmoidal Emax plot generated in vitro. These data were not significantly different from the results produced in vivo. It is concluded that oxindanac causes reversible inhibition of platelet cyclo-oxygenase in calves. Its inhibition of serum TxB2 can be predicted from total plasma drug concentration, as described by a multicompartmental model, and sigmoidal Emax enzyme kinetics. It was not necessary to take into account factors such as drug equilibration between plasma and its target site, free vs. total drug concentration or chirality. This simple model may be useful for predicting the pharmacodynamics of oxindanac in other species.     

Pharmacokinetics, safety, and tolerability of ascending single doses of moxifloxacin, a new 8-methoxy quinolone, administered to healthy subjects

The pharmacokinetics of moxifloxacin were investigated in six studies after oral administration of 50, 100, 200, 400, 600, and 800 mg. Eight healthy male volunteers were included in each study. With doses of up to 200 mg the study was performed as a double-blind, randomized group comparison (n = 6 verum and n = 2 matched placebo); with the higher doses the study was conducted with a double-blind, randomized, crossover design. Safety and tolerability were assessed by evaluation of vital signs, electrocardiograms, electroencephalograms, clinical chemistry parameters, results of urinalysis, and adverse events. The drug was well tolerated. The concentrations of moxifloxacin in plasma, urine, and saliva were determined by a validated high-pressure liquid chromatography assay with fluorescence detection. In addition, plasma and urine samples were analyzed by a bioassay. A good correlation between both methods was seen, indicating an absence of major active metabolites. The mean maximum concentrations of moxifloxacin in plasma (Cmax) ranged from 0.29 mg/liter (50-mg dose) to 4.73 mg/liter (800-mg dose) and were reached 0.5 to 4 h following drug administration. After reaching the Cmax, plasma moxifloxacin concentrations declined in a biphasic manner. Within 4 to 5 h they fell to about 30 to 55% of the Cmax, and thereafter a terminal half-life of 11 to 14 h accounted for the major part of the area under the concentration-time curve (AUC). During the absorption phase concentrations in saliva were even higher than those in plasma, whereas in the terminal phase a constant ratio of the concentration in saliva/concentration in plasma of between 0.5 and 1 was observed, indicating a correlation between unbound concentrations in plasma and levels in saliva (protein binding level, approximately 48%). AUC and Cmax increased proportionally to the dose over the whole range of doses investigated. Urinary excretion amounted to approximately 20% of the dose. Data on renal clearance (40 to 51 ml/min/1.73 m2) indicated partial tubular reabsorption of the drug. The pharmacokinetic parameters derived from compartmental and noncompartmental analyses were in good agreement. The kinetics could be described best by fitting the data to a two-compartment body model.     

No identifiable effect of ginseng (Gericomplex) as an adjuvant in the treatment of geriatric patients

The pharmacokinetics of cefixime, a third-generation broad-spectrum cephalosporin, were determined following administration of a 8 mg/kg single oral dose of cefixime suspension to six children with urinary tract infections, ages from 6 to 13 years and weights from 17 to 60 kg. Blood samples for determination of plasma cefixime concentrations were obtained for up to 12 hr and complete urine collections were obtained for urinary excretion of unchanged parent drug for up to 24 hr after administration. Plasma and urine concentrations of cefixime were determined using a reversed phase HPLC assay and pertinent pharmacokinetic parameters were estimated by model-independent standard methods. Mean peak plasma concentration was 4.04 micrograms/ml and was reached after 3.2 hr. The mean area under the plasma concentration-time curve was 33.07 micrograms.hr/ml and the mean elimination half-life was 3.91 hr. The mean apparent total clearance was 4.74 ml/min./kg and about 15% of the dose administered was recovered unchanged in urine. In conclusion, the estimated pharmacokinetic values of cefixime were comparable to those observed in healthy adult subjects based on equivalent mg/ kg doses. Plasma and urine concentrations of the drug were well above the reported minimal plasma and urinary concentrations for most common urinary tract pathogens for up to 12 and 24 hr after administration, respectively.