Phase Ib trial of intravenous recombinant humanized monoclonal antibody to vascular endothelial growth factor in combination with chemotherapy in patients with advanced cancer: pharmacologic and long-term safety data.

PURPOSE: Tumor angiogenesis mediated by vascular endothelial growth factor (VEGF) is inhibited by the recombinant humanized (rhu) monoclonal antibody (MAb) rhuMAbVEGF, which has synergy with chemotherapy in animal models. The present study was designed to assess the safety and pharmacokinetics of weekly intravenous (IV) rhuMAbVEGF with one of three standard chemotherapy regimens. PATIENTS AND METHODS: Twelve adult patients were enrolled four on each combination. rhuMAbVEGF, 3 mg/kg IV, was administered weekly for 8 weeks with (1) doxorubicin 50 mg/m(2) every 4 weeks; (2) carboplatin at area under the curve of 6 plus paclitaxel 175 mg/m(2) every 4 weeks; and (3) fluorouracil (5-FU) 500 mg/m(2) with leucovorin 20 mg/m(2) weekly, weeks 1 to 6 every 8 weeks. RESULTS: The median number of rhuMAbVEGF doses delivered was eight (range, four to eight doses). Grade 3 toxicities were diarrhea (one 5-FU patient), thrombocytopenia (two patients on carboplatin plus paclitaxel), and leukopenia (one patient on carboplatin plus paclitaxel). These toxicities were likely attributable to the chemotherapy component of the regimen. The mean (+/- SD) peak serum level of rhuMAbVEGF was 167 +/- 46 microg/mL, and the mean terminal half-life was 13 days. Total (free plus bound) serum VEGF levels increased from 51 +/- 39 pg/mL (day 0) to 211 +/- 112 (day 49) pg/mL. Three responding patients continued treatment with rhuMAbVEGF and chemotherapy, receiving the equivalent of 36, 20, and 40 total rhuMAbVEGF doses with no cumulative or late toxicities. CONCLUSION: rhuMAbVEGF can be safely combined with chemotherapy at doses associated with VEGF blockade and without apparent synergistic toxicity. Its contribution to the treatment of advanced solid tumors should be evaluated in randomized treatment trials.

Mixed-effects modeling of the pharmacodynamic response to the calcimimetic agent R-568.

OBJECTIVE: The parathyroid cell calcium receptor is a novel drug target for affecting parathyroid hormone (PTH) secretion and for treating hyperparathyroidism. R-568 is a calcium receptor agonist that inhibits PTH secretion and increases calcitonin release in preclinical studies. The objective of this study was to evaluate the effect of R-568 on PTH plasma concentrations in humans. METHODS: Eighteen healthy postmenopausal women were included in the study. Single ascending oral doses of 10 to 400 mg were administered in a randomized, placebo-controlled double-blind trial. PTH plasma concentrations were measured for up to 120 hours after each dose. RESULTS: R-568 caused a dose-dependent decrease in plasma PTH, with peak effect observed within 1/2 to 2 hours after dosing. The maximum effect did not increase beyond doses from 80 to 160 mg, but duration of response increased at higher doses. An indirect-response model was developed to estimate the rates of input and output of the active moiety(ies), the inhibitory effect on PTH secretion, and the circadian variability in PTH. Population parameter estimates were 3.02 hour-1 and 0.49 hour-1 for rates of input and output of the active moiety(ies), respectively, IA50 (the unscaled amount of R-568 associated with 50% of Emax) was 16.3 mg, Emax (the maximum effect caused by R-568 expressed as a fraction of the rate of PTH secretion in the absence of any drug effect) was 89%, CPTH(baseline) (the baseline PTH plasma concentration in the absence of any drug effect) was 34.6 pg/mL, KePTH (the elimination rate constant for PTH) was 1.73 hour-1, amplitude of the circadian variability in PTH secretion was 5.8%, and the time of peak PTH secretion occurred at about 6 PM. Intersubject variability in parameter estimates ranged from 7% to 121%, and residual variability was 22%. CONCLUSION: The model correctly described the onset, extent, and duration of effect on PTH after a wide range of doses of R-568.

Truncated area under the curve as a measure of relative extent of bioavailability: evaluation using experimental data and Monte Carlo simulations.

PURPOSE: The use of truncated areas under the curve (AUCs) could be a significant advantage for bioequivalence studies of drugs with long half-lives. The purpose of this study was to evaluate the performance of truncated AUCs as measures of relative extent of bioavailability using a large database of experimental data and Monte Carlo simulations. METHODS: The experimental data consisted of 123 single-dose, 2-treatment, crossover studies with at least 18 subjects/study. Monte Carlo techniques were also used to simulate studies that reflected a wide variety of experimental conditions. AUCs were calculated over different time intervals and the standard two one-sided t tests procedure was used to assess bioequivalence. RESULTS: The experimental data showed that conclusions concerning bioequivalence were identical between AUCs truncated at four times the time of peak concentration (Tmax) and AUCs extrapolated to infinity (AUC(inf)) in 120/123 or 97.6% of studies. There was little change in the intra-subject CVs for AUCs truncated at 3*Tmax or later. The results of Monte Carlo simulations were generally consistent with the experimental data and showed that AUCs truncated at 72 hours (AUC(0-72)) performed well compared to AUC(inf) as measures of bioequivalence for drugs with long half-lives. CONCLUSIONS: Based on both the experimental and simulated data, AUCs truncated after the absorption phase perform well as measures of relative extent of bioavailability. Truncated AUCs offer a particular advantage for drugs with long half-lives and these results indicate that it would be reasonable to limit the sample collection period to 72 hours in bioequivalence studies of oral formulations.

Anticonvulsant pharmacodynamics and disposition of triazolam in rats.

Triazolam (TZ) is a triazolobenzodiazepine used in the treatment of insomnia that possesses significant anticonvulsant properties. Despite the widespread use of this drug, detailed pharmacokinetic-pharmacodynamic information is lacking, especially with respect to inhibition of seizure activity. TZ disposition has been described previously by methods with limited specificity, and the concentration-anticonvulsant effect relationship has not been characterized. The current studies were undertaken to examine TZ disposition with a specific HPLC method, and to evaluate the relationship between anticonvulsant effect and concentration in Sprague-Dawley rats. TZ pharmacokinetics were characterized after bolus or infusion administration; in a separate experiment, TZ pharmacodynamics were assessed with pentylenetetrazol-induced seizures. The systemic disposition of TZ could be described with a two-compartment model; systemic clearance ranged from 2.45 to 5.30 L/h/ kg, steady-state volume of distribution ranged from 2.10 to 4.02 L/kg, and mean residence time ranged from 47 to 65 min. The concentration-effect relationship was well described by a simple Emax model: Emax, expressed as the ratio of post-TZ to pre-TZ threshold convulsant doses of pentylenetetrazol, was 9.9 +/- 0.7, and the EC50 values were 10.0 +/- 4.6 ng/mL and 34.8 +/- 9.0 ng/g in serum and whole brain tissue, respectively. Under single-dose conditions, TZ is a very potent anticonvulsant in the rat pentylenetetrazol seizure model.

Population pharmacokinetics of terfenadine.

PURPOSE: After oral administration of terfenadine, plasma concentrations of the parent drug are usually below the limits of quantitation of conventional analytical methods because of extensive first-pass metabolism. Data are usually reported on the carboxylic acid metabolite (M1) but there are no published reports of pharmacokinetic parameters for terfenadine itself. The present study was undertaken to evaluate the population pharmacokinetics of terfenadine. METHODS: Data from 132 healthy male subjects who participated in several different studies were included in this analysis. After an overnight fast, each subject received a single 120 mg oral dose of terfenadine; blood samples were collected for 72 hours. Terfenadine plasma concentrations were measured using HPLC with mass spectrometry detection and M1 plasma concentrations were measured using HPLC with fluorescence detection. A 2-compartment model was fitted to the terfenadine data using NONMEM; terfenadine and M1 data were also analyzed by noncompartmental methods. RESULTS: Population mean Ka was 2.80 hr-1, Tlag was 0.33 hr, Cl/F was 4.42 x 10(3) 1/hr, Vc/F was 89.8 x 10(3) 1. Q/F was 1.85 x 10(3) 1/hr and Vp/F was 29.1 x 10(3) 1. Intersubject CV ranged from 66 to 244% and the residual intrasubject CV was 21%. Based on noncompartmental methods, mean terfenadine Cmax was 1.54 ng/ml, Tmax was 1.3 hr, t1/2 lambda Z was 15.1 hr, Cl/F was 5.48 x 10(3) 1/hr and V lambda Z/F was 119.2 x 10(3) 1. M1 concentrations exceeded terfenadine concentrations by more than 100 fold and showed less intersubject variability. CONCLUSIONS: Terfenadine disposition was characterized by a 2-compartment model with large intersubject variability, consistent with its significant first-pass effect.

Pharmacokinetics and anticonvulsant effect of a new hypnotic, CL 284,846, in rats.

PURPOSE: CL 284,846 (CL846) is an investigational non-benzodiazepine agent with hypnotic, anxiolytic, myorelaxant and anticonvulsant properties. This study assessed the pharmacokinetics and anticonvulsant action of CL846 in female Sprague-Dawley rats. METHODS: CL846 pharmacokinetics were examined after either an iv bolus dose (2.5 mg/kg) or a 6-hr infusion (0.4 mg/kg/hr). CL846 pharmacodynamics were evaluated with a pentylenetetrazol (PTZ) infusion 5 min after a CL846 in bolus dose (0 to 10 mg/kg). CL846 and the derived metabolite CL 284,859 (CL859) concentrations in serum and brain tissue were determined by HPLC with fluorescence detection. RESULTS: Both the steady-state volume of distribution (1636 +/- 162 and 1804 +/- 293 ml/kg, after bolus and infusion administration, respectively) and systemic clearance (19.1 +/- 7.1 and 22.2 +/- 4.3 ml/min/kg for bolus and infusion administration, respectively) were high. No differences in pharmacokinetic parameters were noted between the two modes of administration. The relationship between anticonvulsant effect and brain/serum concentrations was well described by an Emax model. CL846 was as effective as triazolam in antagonizing PTZ-induced seizures. CONCLUSIONS: Under the conditions of the present study, CL846 pharmacokinetics were linear and stationary. Further evaluation of the anticonvulsant properties of CL846 is warranted, including the potential development of tolerance, which is well known for benzodiazepines.

A placebo-controlled evaluation of single, escalating doses of CL 284,846, a non-benzodiazepine hypnotic.

This report describes the first evaluation in humans of CL 284,846, a non-benzodiazepine compound with a preclinical profile indicative of sedative/hypnotic properties. Healthy, normal male volunteers were assigned randomly to receive single oral doses of 1, 5, 15, 30, or 60 mg of CL 284,846 or placebo on a double-blind basis. Observations were made over the subsequent 25 hours to determine the safety, pharmacokinetic profile, and psychometric effects of the test compound. CL 284,846 was well tolerated in the normal volunteers, causing no significant changes in vital signs, EEG, ECG, hematologic, or clinical chemistry laboratory parameters. Although few adverse events were noted at doses less than 60 mg, at the highest dose (60 mg), all volunteers reported transient neurologically related adverse events (e.g., impaired concentration, difficulty focusing, and impaired coordination), reflecting the central nervous system action of the compound. Although determination of hypnotic efficacy was not an objective in this Phase I study, daytime treatment with 60 mg of CL 284,846 was associated with greater reports of drowsiness and impaired performance on psychomotor tests. However, memory, as assessed by a word recall test, was not affected at any dose of the compound. Pharmacokinetic analyses revealed CL 284,846 to be absorbed and eliminated rapidly (Tmax = 0.9-1.5 hr, T 1/2 = 0.9-1.1 hr), with a dose-proportional AUC (area under cure). Plasma levels of CL 284,859, the primary desethylated metabolite of CL 284,846, were much lower in humans than in other species, indicating that the metabolism of CL 284,846 in humans may differ from that of rodents and dogs. Overall, CL 284,846 was well tolerated, and the authors recommend repeating dose safety and pharmacokinetic studies in healthy volunteers.