Anne N. Nafziger

Physiological Changes During the Menstrual Cycle and Their Effects on the Pharmacokinetics and Pharmacodynamics of Drugs

There is an increasing awareness that the exclusion of women from clinical trials may lead to inaccurate application of drug therapy in women. Gender and estrus cycle differences in the pharmacokinetics and pharmacodynamics of drugs in animals have been appreciated for over 60 years, but investigation into these differences in humans has only recently occurred.It is postulated that hormonal fluctuations within the menstrual cycle phase may be a primary cause of documented gender differences in the pharmacokinetics and pharmacodynamics of drugs. Existing data suggest that menstrual cycle variations do occur in renal, cardiovascular, haematological and immune systems. These physiological changes could potentially impact on the pharmacokinetics or pharmacodynamics of drugs by altering properties, such as protein binding or the volume of distribution, and thereby causing significant effects at various times during the menstrual cycle. However, systematic investigations of physiological variability throughout the menstrual cycle are limited.Fluctuations in symptom severity and clinical course coinciding with the menstrual cycle phase have been seen in some diseases. Hormonal fluctuations within the menstrual cycle have been postulated to cause disease exacerbation. They may also worsen disease severity by impacting on the pharmacokinetics or pharmacodynamics of the medication.Menstrual cycle hormonal changes may influence drug absorption, distribution, metabolism or excretion. In vivo data to demonstrate an effect of endogenous estrogen or progesterone on pharmacokinetics are limited and contradictory.Systematic investigations of specific pharmacokinetic and pharmacodynamic changes within the menstrual cycle are lacking. Most published studies have been conducted with small numbers of women and a limited numbers of menstrual cycle phases within 1 menstrual cycle. These design problems have resulted in incomplete data for assessing the effects of the menstrual cycle. To date, there are no demonstrated clinically significant changes that occur in the absorption, distribution or elimination of drugs. With respect to drug metabolism, data are exceedingly sparse and have been collected in a suboptimal fashion. Standardisation of study design and analyses in systematic investigations of the influence of the menstrual cycle on drug pharmacokinetics and pharmacodynamics are needed.

Individualized pharmacokinetic monitoring results in less aminoglycoside-associated nephrotoxicity and fewer associated costs.

Study Objective. To examine the impact of individualized pharmacokinetic monitoring (IPM) on the development of aminoglycoside‐associated nephrotoxicity (AAN).

Randomized Study of Paclitaxel and Tamoxifen Deposition into Human Brain Tumors: Implications for the Treatment of Metastatic Brain Tumors

Purpose: Drug resistance in brain tumors is partially mediated by the blood-brain barrier of which a key component is P-glycoprotein, which is highly expressed in cerebral capillaries. Tamoxifen is a nontoxic inhibitor of P-glycoprotein. This trial assessed, in primary and metastatic brain tumors, the differential deposition of paclitaxel and whether tamoxifen could increase paclitaxel deposition. Experimental Design: Patients for surgical resection of their primary or metastatic brain tumors were prospectively randomized to prior paclitaxel alone (175 mg/m2/i.v.) or tamoxifen for 5 days followed by paclitaxel. Central and peripheral tumor, surrounding normal brain and plasma, were analyzed for paclitaxel and tamoxifen. Results: Twenty-seven patients completed the study. Based on a multivariate linear regression model, no significant differences in paclitaxel concentrations between the two study arms were found after adjusting for treatment group (tamoxifen versus control). However, in analysis for tumor type, metastatic brain tumors had higher paclitaxel concentrations in the tumor center (1.93-fold, P = 0.10) and in the tumor periphery (2.46-fold, P = 0.039) compared with primary brain tumors. Pharmacokinetic analyses showed comparable paclitaxel areas under the serum concentration between treatment arms. Conclusions: Paclitaxel deposition was not increased with this tamoxifen schedule as the low plasma concentrations were likely secondary to concurrent use of P-450-inducing medications. However, the statistically higher paclitaxel deposition in the periphery of metastatic brain tumors provides functional evidence corroborating reports of decreased P-glycoprotein expression in metastatic versus primary brain tumors. This suggests that metastatic brain tumors may respond to paclitaxel if it has proven clinical efficacy for the primary tumors histopathology.

Evaluation of in vivo P-glycoprotein phenotyping probes: a need for validation.

Drug transporters are involved in clinically relevant drug-drug interactions. P-glycoprotein (P-gp) is an efflux transporter that displays genetic polymorphism. Phenotyping permits evaluation of real-time, in vivo P-gp activity and P-gp-mediated drug-drug interactions. Digoxin, fexofenadine, talinolol and quinidine are commonly used probe drugs for P-gp phenotyping. Although current regulatory guidance documents highlight methodologies for evaluating transporter-based drug-drug interactions, whether current probe drugs are suitable for phenotyping has not been established, and validation criteria are lacking. This review proposes validation criteria and evaluates P-gp probes to determine probe suitability. Based on these criteria, digoxin, fexofenadine, talinolol and quinidine have limitations to their use and are not recommended for P-gp phenotyping.

Limited Sampling Strategy to Predict AUC of the CYP3A Phenotyping Probe Midazolam in Adults: Application to Various Assay Techniques

Midazolam clearance is used to phenotype hepatic CYP3A activity but requires multiple plasma samples following a single intravenous dose. The authors evaluated the use of a limited sampling scheme, using different assay techniques to determine the reproducibility of such a strategy in estimating midazolam AUC. Seventy‐three healthy adults received midazolam as a single intravenous bolus dose. At least eight plasma samples were collected from each subject and were assayed using either LC/MS/MS or electron capture gas chromatography. Eleven subjects were randomly selected for the training set using stepwise linear regression to determine relationships between midazolam plasma concentrations and AUC. Validation of the predictive equations was done using the remaining 62 subjects. Mean percent error (MPE), mean absolute error (MAE), and root mean square error (RMSE) were calculated to determine bias and precision. Based on the training set, five models were generated with coefficients of determination ranging from 0.87 to 0.95. Validation showed that MPE, MAE, and RMSE values were acceptable for three of the models. Int rasubject reproducibility was good. In addition, training set data from one institution were able to predict data from the other two institutions using other assay techniques. Minimized plasma sampling may provide a simpler method for estimating midazolam AUC for CYP3A phenotyping. A limited sampling strategy is more convenient and cost‐effective than standard sampling strategies and is applicable to more than one assay technique.

Comparison of 30-min and 3-h infusion regimens for imipenem/cilastatin and for meropenem evaluated by Monte Carlo simulation.

Imipenem/cilastatin and meropenem are carbapenem antibiotics that are infused intravenously (IV) over 30 to 45 min. We evaluated probability of target attainment and cumulative probability of target attainment of 30-min and 3-h infusions for imipenem/cilastatin and meropenem. Eighteen healthy adults in a randomized, 4-phase, crossover study received 1000 mg of imipenem/cilastatin or meropenem as a single-dose IV over 30 min or 3 h. A population pharmacokinetics analysis using a 2-compartment IV infusion model was performed. Monte Carlo simulations using various dosage regimens at steady-state and 30-min and 3-h infusion rates were performed to evaluate the probabilities of attaining 20% (bacteriostatic), 30%, and 40% (maximum kill) time above the MIC. Three-hour infusions of imipenem/cilastatin and meropenem improved the cumulative probability of target attainment for a variety of populations of microorganisms compared to 30-min infusions. Prolonged infusions have the potential to optimize efficacy of imipenem/cilastatin and meropenem.

Maribavir Pharmacokinetics and the Effects of Multiple-Dose Maribavir on Cytochrome P450 (CYP) 1A2, CYP 2C9, CYP 2C19, CYP 2D6, CYP 3A, N-Acetyltransferase-2, and Xanthine Oxidase Activities in Healthy Adults

ABSTRACT Maribavir (1263W94, VP-41263) is an oral anticytomegalovirus agent under clinical development. The pharmacokinetics and safety of maribavir and the effects of maribavir on the activities of cytochrome P450 (CYP) 1A2, CYP 2C9, CYP 2C19, CYP 2D6, CYP 3A, N-acetyltransferase-2 (NAT-2), and xanthine oxidase (XO) were evaluated in a randomized, double-blind, placebo-controlled study. Twenty healthy subjects received a five-drug phenotyping cocktail of caffeine (CYP 1A2, NAT-2, XO), warfarin plus vitamin K (CYP 2C9), omeprazole (CYP 2C19), dextromethorphan (CYP 2D6), and midazolam (CYP 3A) 4 days before and after 7 days of treatment with maribavir at 400 mg twice daily (16 subjects) or placebo (4 subjects) for 10 days. Maribavir did not affect the CYP 1A2, CYP 2C9, CYP 3A, NAT-2, or XO activities. Bioequivalence was not demonstrated for CYP 2C19 and CYP 2D6, suggesting a decrease or inhibition of CYP 2C19 and CYP 2D6 activities. The pharmacokinetics of maribavir following a single dose and after 10 days of treatment were similar, with minimal accumulation at steady state. Maribavir was safe and well tolerated. Taste disturbance was the most frequently reported adverse event. These results will further guide evaluation of the drug interaction potential and clinical development of maribavir.

Inhibition of Theophylline Elimination by Diltiazem Therapy

To investigate the effects of diltiazem on theophylline pharmacokinetics, nine healthy male subjects (four smokers and five nonsmokers) received intravenous aminophylline (6 mg/kg) prior to and following 10 days of oral diltiazem therapy. Theophylline half‐life increased significantly whereas total body clearance showed a significant decrease following diltiazem. Volume of distribution was unchanged. The small group of smokers had a significantly greater increase in theophylline half‐life than the nonsmokers. Inhibition of metabolism of theophylline by diltiazem likely explains the significant changes in theophylline pharmacokinetics. A clinically important drug interaction may occur with theophylline when diltiazem therapy is given concurrently.

Genetic polymorphisms of cytochrome P450 enzymes and the effect on interindividual, pharmacokinetic variability in extensive metabolizers.

Genetic polymorphisms of cytochrome P450 (CYP) enzymes are one of the factors that contribute to the pharmacokinetic (PK) variability of drugs. PK variability is observed in the bimodal distribution between extensive metabolizers (EMs) and poor metabolizers (PMs). PK variability may also exist between individuals genotyped as homozygous EMs and heterozygous EMs. This may carry implications for drug dosing and drug response (e.g., risk of therapeutic failure or drug toxicity). Studies have reported significant PK differences between homozygous and heterozygous EMs. Some literature suggests that this distinction may be of clinical relevance. Due to study design limitations and data that are either sparse or conflicting, generalizations regarding the potential impact of the CYP genotype, within EMs, are difficult. Optimally designed clinical trials are needed. This review evaluates the potential impact of CYP genetic polymorphisms on interindividual PK variability of drugs within an EM population.

The effect of oral pleconaril on hepatic cytochrome P450 3A activity in healthy adults using intravenous midazolam as a probe.

Pleconaril is a viral capsid inhibitor under evaluation for treatment of infections caused by rhinoviruses and enteroviruses. This study evaluated the effect of pleconaril on hepatic cytochrome P450 (CYP) 3A activity as assessed by intravenous (IV) midazolam. Healthy adults received oral pleconaril 400 mg 3 times daily for 16 doses. Single‐dose, IV midazolam 0.025 mg/kg was administered before and during pleconaril administration. Midazolam and pleconaril plasma concentrations were assayed by LC/MS/MS. Bioequivalence was assessed by least squares geometric mean ratios (LS‐GMR) with 90% confidence intervals (90% CIs) for the measured midazolam pharmacokinetic parameters. Sixteen subjects were enrolled, and 14 subjects completed the study. Pleconaril decreased midazolam AUC0‐∞ 28% and increased systemic clearance 39%. LS‐GMR (90% CI) were 0.718 (0.674–0.765) and 1.392 (1.307–1.483), respectively. Plasma pleconaril concentrations steadily increased over time. Observed changes in midazolam AUC0‐∞ and systemic clearance suggest that oral pleconaril increased hepatic CYP3A activity in healthy adults.