Luann Phillips

Population Pharmacokinetics and Pharmacodynamics of Garenoxacin in Patients with Community-Acquired Respiratory Tract Infections

ABSTRACT Garenoxacin (T-3811ME, BMS-284756) is a novel, broad-spectrum des-F(6) quinolone currently under study for the treatment of community-acquired respiratory tract infections. This analysis assessed garenoxacin population pharmacokinetics and exposure-response relationships for safety (adverse effects [AE]) and antimicrobial activity (clinical cure and bacteriologic eradication of Streptococcus pneumoniae and the grouping of Haemophilus influenzae, Haemophilus parainfluenzae, and Moraxella catarrhalis). Data were obtained from three phase II clinical trials of garenoxacin administered orally as 400 mg once daily for 5 to 10 days for the treatment of community-acquired pneumonia, acute exacerbation of chronic bronchitis, and sinusitis. Samples were taken from each patient before drug administration, 2 h following administration of the first dose, and on the day 3 to 5 visit. Individual Bayesian estimates of the fu (fraction unbound), the Cmax, and the fu for the area under the concentration-time curve from 0 to 24 h (fu AUC0-24) were calculated as measurements of drug exposure by using an ex vivo assessment of average protein binding. Regression analysis was performed to examine the following relationships: treatment-emergent AE incidence and AUC0-24, Cmax, or patient factors; clinical response or bacterial eradication and drug exposure (fu Cmax/MIC, fu AUC0-24/MIC, and other exposure covariates); or disease and patient factors. Garenoxacin pharmacokinetics were described by a one-compartment model with first-order absorption and elimination. Clearance was dependent on creatinine clearance, ideal body weight, age, obesity, and concomitant use of pseudoephedrine. The volume of distribution was dependent on weight and gender. Patients with mild or moderate renal dysfunction had, on average, approximately a 16 or 26% decrease in clearance, respectively, compared to patients of the same gender and obesity classification with normal renal function. AE occurrence was not related to garenoxacin exposure. Overall, clinical cure and bacterial eradication rates were 91 and 90%, respectively, for S. pneumoniae and 93 and 92%, respectively, for the grouping of H. influenzae, H. parainfluenzae, and M. catarrhalis. The fu AUC0-24/MIC ratios were high (>90% were >200), and none of the pharmacokinetic-pharmacodynamic exposure measurements indexed to the MIC or other factors were significant predictors of clinical or bacteriologic response. Garenoxacin clearance was primarily related to creatinine clearance and ideal body weight. Although garenoxacin exposure was approximately 25% higher for patients with moderate renal dysfunction, this increase does not appear to be clinically significant as exposures in this patient population were not significant predictors of AE occurrence. Garenoxacin exposures were at the upper end of the exposure-response curves for measurements of antimicrobial activity, suggesting that 400 mg of garenoxacin once daily is a safe and adequate dose for the treatment of the specified community-acquired respiratory tract infections.

Prospective Use of Population Pharmacokinetics/ Pharmacodynamics in the Development of Cisatracurium

AbstractPurpose. The population PK/PD approach was prospectively used to determine the PK/PD of cisatracurium in various subgroups of healthy surgical patients. Methods. Plasma concentration (Cp) and neuromuscular block data from 241 patients in 8 prospectively-designed Phase I−III trials were pooled and analyzed using NONMEM. The analyses included limited Cp-time data randomly collected from 186 patients in efficacy/safety studies and full Cp-time data from 55 patients in pharmacokinetic studies. The effects of covariates on the PK/PD parameters of cisatracurium were evaluated. The time course of neuromuscular block was predicted for various patient subgroups. Results. The population PK/PD model for cisatracurium revealed that anesthesia type, gender, age, creatinine clearance, and presence of obesity were associated with statistically significant (p < 0.01) effects on the PK/PD parameters of cisatracurium. These covariates were not associated with any clinically significant changes in the predicted recovery profile of cisatracurium. Slight differences in onset were predicted in patients with renal impairment and patients receiving inhalation anesthesia. Based on the validation procedure, the model appears to be accurate and precise. Conclusions. The prospective incorporation of a population PK/PD strategy into the clinical development of cisatracurium generated information which influenced product labeling and reduced the number of studies needed during development.

A population pharmacokinetic-pharmacodynamic analysis and model validation of azimilide.

Pharmacokinetic (PK) and pharmacodynamic (PD) models for azimilide were developed and validated with sparse blood sampling and QTc interval data obtained during three clinical trials of azimilide for prevention of supraventricular arrhythmia recurrence.

Dose Proportionality of Cisatracurium

The dose proportionality of cisatracurium pharmacokinetics was assessed using a population approach by incorporating the collection of sparse blood samples from patients in clinical trials. Plasma concentration—time data from 131 patients with limited concentration—time data and 38 patients with full sampling were pooled and analyzed using nonlinear mixed‐effects modeling (NONMEM). Dose proportionality was assessed using dichotomous parameterization and a linear model. The population pharmacokinetic approach revealed that the pharmacokinetics of cisatracurium are independent of dose between 0.1 mg/kg and 0.4 mg/kg, as was expected based on the importance of Hofmann elimination, a chemical process dependent on pH and temperature.

Population pharmacokinetics and pharmacokinetics/pharmacodynamics of bendamustine in pediatric patients with relapsed/refractory acute leukemia

Abstract Objective: The pharmacokinetic (PK) profile of bendamustine has been characterized in adults with indolent non-Hodgkin lymphoma (NHL), but remains to be elucidated in pediatric patients with hematologic malignancies. This analysis used data from a nonrandomized pediatric study in patients with relapsed/refractory acute lymphocytic leukemia or acute myeloid leukemia. Methods: Bendamustine 90 or 120 mg/m2 (60-minute infusion) was administered on days 1 and 2 of 21 day cycles. The population PK base model was adjusted for body surface area (BSA), and the appropriateness of the final model was evaluated by visual predictive check. A covariate analysis explored PK variability. Bayesian PK parameter estimates and concentration–time profiles for each patient were generated. Bendamustine PK in pediatric patients was compared with that of adults with indolent NHL. PK/pharmacodynamic analyses were conducted for fatigue, nausea, vomiting, and infection. Results: Thirty-eight patients (median age: 7 years; range: 1–19 years) receiving bendamustine 120 mg/m2 and an additional five patients receiving bendamustine 90 mg/m2 (median age: 12 years; range: 8–14 years) were included in the population PK analysis. Peak plasma concentrations of bendamustine (Cmax) occurred at the end of infusion (about 1 h). Decline from peak showed a rapid distribution phase (t½α = 0.308 h) and a slower elimination phase (t½β = 1.47 h). Model-predicted mean Cmax and area under the curve values from time 0–24 h were 6806 ng/mL and 8240 ng*h/mL, respectively. When dosed based upon BSA, it appeared that age, body weight, race, mild renal (n = 3) or hepatic (n = 2) dysfunction, cancer type, and cytochrome P450 1A2 inhibitors (n = 17) or inducers (n = 3) did not affect systemic exposure, which was comparable between pediatric and adult patients. Infection was the only adverse event associated with bendamustine Cmax. However, due to the small sample size for some subgroups, the observed trends should be interpreted with caution. Conclusions: At the recommended dose (120 mg/m2), bendamustine systemic exposure was similar across the pediatric population and comparable to adults. The similarity in exposure despite the large range of BSA across pediatric and adult populations confirms the appropriateness of BSA-based dosing, which was utilized to attain systemic exposures in pediatric patients reflective of the therapeutic range in adults. Probability of occurrence of infection increased with higher bendamustine Cmax.

Population Pharmacokinetic Evaluation and Missed‐Dose Simulations for Eslicarbazepine Acetate Monotherapy in Patients With Partial‐Onset Seizures

Given the potential consequences of antiepileptic therapy nonadherence, missed‐dose scenarios of 12‐ to 48‐hour dose delays (4‐hour intervals) for eslicarbazepine acetate monotherapy were evaluated using simulated plasma concentrations of a population pharmacokinetic model (representing 493 subjects). When 1600‐mg doses were delayed 12 to <16 or 36 to <44 hours, simulations showed immediate administration of 1600 mg followed by the same dose at the scheduled time maintained plasma concentrations within the target concentration range. With 16‐ to 24‐ or 44‐ to 48‐hour delays, administration of 2400 mg at the scheduled time followed by resumption of 1600 mg/day maintained plasma concentrations within the target concentration range. For exploratory purposes, the population pharmacokinetic model was refined to predict (n = 6 subjects) and also to allow for simulation of cerebrospinal fluid concentrations. Based on the plasma concentration simulations conducted herein, potential dosing recommendations were developed that suggest a missed ESL dose should be taken when remembered, and the usual dose regimen resumed. If it is remembered within 4 hours of the next dose, 1.5 times the usual dose should be taken immediately, the scheduled dose for that day should be skipped, and the usual regimen resumed the next day.

Model-Informed Drug Development for Malaria Therapeutics

Malaria is a critical public health problem resulting in substantial morbidity and mortality, particularly in developing countries. Owing to the development of resistance toward current therapies, novel approaches to accelerate the development efforts of new malaria therapeutics are urgently needed. There have been significant advancements in the development of in vitro and in vivo experiments that generate data used to inform decisions about the potential merit of new compounds. A comprehensive disease-drug model capable of integrating discrete data from different preclinical and clinical components would be a valuable tool across all stages of drug development. This could have an enormous impact on the otherwise slow and resource-intensive process of traditional clinical drug development.