Pharmacokinetics of licarbazepine in healthy volunteers: single and multiple oral doses and effect of food.

Two studies characterized single- and multiple-dose pharmacokinetics of licarbazepine immediate-release tablets and food effects on single-dose pharmacokinetics. In 1 study, 12 volunteers received 500 mg licarbazepine on day 1, 500 mg bid on days 3 to 6, and 500 mg on day 7. In the second study, 12 subjects received one 500-mg licarbazepine dose under fasted and fed conditions. After multiple dosing, geometric mean (%CV) Cmax ss, Cmin ss, and AUCtau were 77.6 micromol/L (18), 45.3 micromol/L (25), and 747 h.mol/L (19), respectively, with a tmax of 2 hours. Mean half-lives were 9.3 and 11.3 hours for single and multiple dosing, respectively. Food had no clinically significant effect on single-dose pharmacokinetics. Half-life ( approximately 10 hours) and low intersubject variability in main pharmacokinetic parameters were similar under fasted and fed conditions. Median tmax increased from 1.5 to 2.5 hours with food. Licarbazepine is well tolerated and has predictable pharmacokinetics.

Metabolism and disposition of vatalanib (PTK787/ZK-222584) in cancer patients.

Vatalanib (PTK787/ZK-222584) is a new oral antiangiogenic molecule that inhibits all known vascular endothelial growth factor receptors. Vatalanib is under investigation for the treatment of solid tumors. Disposition and biotransformation of vatalanib were studied in an open-label, single-center study in patients with advanced cancer. Seven patients were given a single oral (14)C-radiolabeled dose of 1,000 mg of vatalanib administered at steady state, obtained after 14 consecutive daily oral doses of 1,000 mg of nonradiolabeled vatalanib. Plasma, urine, and feces were analyzed for radioactivity, vatalanib, and its metabolites. Metabolite patterns were determined by high-performance liquid chromatography coupled to radioactivity detection with off-line microplate solid scintillation counting and characterized by LC-MS. Vatalanib was well tolerated. The majority of adverse effects corresponded to common toxicity criteria grade 1 or 2. Two patients had stable disease for at least 7 months. Plasma C(max) values of (14)C radioactivity (38.3 +/- 26.0 microM; mean +/- S.D., n = 7) and vatalanib (15.8 +/- 9.5 microM) were reached after 2 and 1.5 h (median), respectively, indicating rapid onset of absorption. Terminal elimination half-lives in plasma were 23.4 +/- 5.5 h for (14)C radioactivity and 4.6 +/- 1.1 h for vatalanib. Vatalanib cleared mainly through oxidative metabolism. Two pharmacologically inactive metabolites, CGP-84368/ZK-260120 [(4-chlorophenyl)-[4-(1-oxy-pyridin-4-yl-methyl)-phthalazin-1-yl]-amine] and NVP-AAW378/ZK-261557 [rac-4-[(4-chloro-phenyl)amino]-alpha-(1-oxido-4-pyridyl)phthalazine-1-methanol], having systemic exposure comparable to that of vatalanib, contributed mainly to the total systemic exposure. Vatalanib and its metabolites were excreted rapidly and mainly via the biliary-fecal route. Excretion of radioactivity was largely complete, with a radiocarbon recovery between 67% and 96% of dose within 7 days (42-74% in feces, 13-29% in urine).

Oxcarbazepine in infants and young children with partial seizures.

In this open-label study, the safety, tolerability, and pharmacokinetics of oxcarbazepine as monotherapy or adjunctive therapy were studied in infants and young children with partial seizures. In a 30-day treatment phase, oxcarbazepine was titrated from 10 mg/kg/day to 60 mg/kg/day. Blood samples for analysis of the oxcarbazepine metabolite, the 10-monohydroxy derivative (MHD), were obtained at regular intervals. Patients completing the treatment phase entered a 6-month extension phase. Safety and tolerability were assessed throughout the study. Twenty-four patients (mean [range] age, 20.4 [2-45] months) were enrolled. Nineteen (79%) patients completed the treatment phase and, together with one patient who discontinued prematurely during the treatment phase, entered the extension phase. Thirteen of 20 (65%) patients completed the extension phase. The most common adverse events were pyrexia, ear infection, and irritability. Whether patients (n = 23) received enzyme-inducing antiepileptic drugs or not, MHD concentrations were consistent with those predicted from a linear, one-compartment, population-pharmacokinetic model based on a model previously fitted for 3- to 17-year-old children. Oxcarbazepine was safe and well tolerated in infants and young children. The pharmacokinetic profile of MHD was predicted by extension of a model based on older children.

Pharmacokinetics and electrocardiographic pharmacodynamics of artemether-lumefantrine (Riamet) with concomitant administration of ketoconazole in healthy subjects.

AIMS: To evaluate whether the potent CYP3A4 inhibitor ketoconazole has any influence on the pharmacokinetic and electrocardiographic parameters of the antimalarial co-artemether (artemether-lumefantrine) in healthy subjects. METHODS: Sixteen subjects were randomized in an open-label, two period crossover design study. Subjects received a single dose of co-artemether (day 1) either alone or in combination with multiple oral doses of ketoconazole (400 mg on day 1 followed by 200 mg o.d. for 4 additional days). Serial blood samples were taken and assayed for artemether and its main active metabolite dihydroartemisinin (DHA), and lumefantrine. RESULTS: The pharmacokinetics of artemether, its metabolite DHA, and lumefantrine were influenced by the presence of ketoconazole. AUC(0, infinity ) was increased from 320 to 740 ng ml-1 h (ratio 2.4, 90% CI 2.00, 2.86) for artemether, from 331 to 501 ng ml-1 h (ratio 1.7, 90% CI 1.40, 1.98) for DHA, and from 207 to 333 micro g ml-1 h (ratio 1.7, 90% CI 1.23, 2.21) for lumefantrine in the presence of ketoconazole. Cmax also increased in similar proportions for the three compounds (ratio 2.2 (90% CI 1.78, 2.83), 1.4 (90% CI 1.12, 1.74), and 1.3 (90% CI 0.96, 1.64), respectively). The terminal elimination half-life was increased for artemether (2.5 vs 1.9 h, 90% CI 1.12, 1.72) and DHA (3.1 vs 2.1 h, 90% CI 0.02, 3.36), but remained unchanged for lumefantrine (88 vs 95 h, 90% CI 0.81, 1.04). These increases in exposure to the antimalarial combination were much smaller than observed with food intake (up to 16 fold), and were not associated with increased side-effects or changes in electrocardiographic parameters. The study medications were well tolerated. CONCLUSIONS: The concurrent administration of ketoconazole with co-artemether led to modest increases in artemether, DHA, and lumefantrine exposure in healthy subjects. Dose adjustment of co-artemether is probably unnecessary in falciparum malaria patients when administered in association with ketoconazole or other potent CYP3A4 inhibitors.

Interaction trial between artemether-lumefantrine (Riamet) and quinine in healthy subjects.

Forty-two healthy Caucasian subjects were randomized in a double-blind, parallel three-group study (14 subjects per group) to investigate potential electrocardiographic and pharmacokinetic interactions between the antimalarials artemether-lumefantrine (six-dose regimen of Riamet over 3 days) and quinine (2-h intravenous infusion of 10 mg/kg body weight, not exceeding 600 mg in total, 2 h after the last dose of Riamet). The study medications were all safe and well tolerated after all treatments. Neither the pharmacokinetics of lumefantrine nor the pharmacokinetics of quinine was influenced by the presence of the other drug. Plasma levels of artemether and dihydroartemisinin appeared to be lower following the combined treatment Riamet + quinine, but this was not considered to be clinically relevant. Riamet alone had no effect on QTc interval. Infusion of quinine alone caused a transient prolongation of QTc interval, which was consistent with the known cardiotoxicity of quinine, with this effect being slightly but significantly greater when quinine was infused after Riamet. It would thus appear that the inherent risk of QTc prolongation of IV quinine was enhanced by prior administration of Riamet. However, these occasional QTc prolongations, which were small in magnitude and not correlated with plasma concentrations of any of the compounds, were not considered to be of clinical importance. In conclusion, overlapping therapy with artemether-lumefantrine and IV quinine in the treatment of patients with complicated or multidrug-resistant Plasmodium falciparum malaria may result in a modest increased risk of QTc prolongation, but this is far outweighed by the potential therapeutic benefit.