Pharmacokinetics and repolarization effects of intravenous and transdermal granisetron.

PURPOSE: The need for greater clarity about the effects of 5-HT(3) receptor antagonists on cardiac repolarization is apparent in the changing product labeling across this therapeutic class. This study assessed the repolarization effects of granisetron, a 5-HT(3) receptor antagonist antiemetic, administered intravenously and by a granisetron transdermal system (GTDS). EXPERIMENTAL DESIGN: In a parallel four-arm study, healthy subjects were randomized to receive intravenous granisetron, GTDS, placebo, or oral moxifloxacin (active control). The primary endpoint was difference in change from baseline in mean Fridericia-corrected QT interval (QTcF) between GTDS and placebo (ddQTcF) on days 3 and 5. RESULTS: A total of 240 subjects were enrolled, 60 in each group. Adequate sensitivity for detection of QTc change was shown by a 5.75 ms lower bound of the 90% confidence interval (CI) for moxifloxacin versus placebo at 2 hours postdose on day 3. Day 3 ddQTcF values varied between 0.2 and 1.9 ms for GTDS (maximum upper bound of 90% CI, 6.88 ms), between -1.2 and 1.6 ms for i.v. granisetron (maximum upper bound of 90% CI, 5.86 ms), and between -3.4 and 4.7 ms for moxifloxacin (maximum upper bound of 90% CI, 13.45 ms). Day 5 findings were similar. Pharmacokinetic-ddQTcF modeling showed a minimally positive slope of 0.157 ms/(ng/mL), but a very low correlation (r = 0.090). CONCLUSION: GTDS was not associated with statistically or clinically significant effects on QTcF or other electrocardiographic variables. This study provides useful clarification on the effect of granisetron delivered by GTDS on cardiac repolarization.

Pharmacokinetics and pharmacodynamics of three moxifloxacin dosage forms: implications for blinding in active-controlled cardiac repolarization studies.

Moxifloxacin is used in thorough QT studies to assess sensitivity for detection of an increase in QTc. Moxifloxacin is usually over-encapsulated for blinding. However, there is concern that over-encapsulation alters its pharmacokinetics. In a 4-arm, randomized crossover study, 22 volunteers received over-encapsulated moxifloxacin, over-encapsulated placebo, bare moxifloxacin, and intravenous (IV) moxifloxacin. Placebo capsules and IV infusions were administered so that treatments in each arm, except for bare moxifloxacin, were indistinguishable. Pharmacokinetics of the oral treatments were found to be nearly identical and to meet Food and Drug Administration criteria for bioequivalency. Relative to the IV infusion administered over 1 hour, the tablet formulation was bioequivalent to total exposure but not peak exposure maximum plasma concentration, which was lower by 22%. Median time to maximum plasma concentration of the IV infusion was 1.00 hour. A 2-compartment model with oral absorption and linear elimination adequately described the observed moxifloxacin data. Changes in QTcF mirrored the pharmacokinetic changes, and there was a linear relationship between plasma concentration of moxifloxacin and change in QTcF. A 2-stage infusion scheme for IV moxifloxacin mimics the oral plasma concentration versus time curve. Over-encapsulation of moxifloxacin did not alter its peak or total systemic exposures or pharmacodynamics after oral administration.

Comparison of the bioavailability of unequal doses of divalproex sodium extended-release formulation relative to the delayed-release formulation in healthy volunteers.

Valproate formulations, divalproex sodium extended-release (ER) and the traditional divalproex sodium delayed-release (DR) formulations, are not bioequivalent. This study evaluated if ER QD regimens with 14 and 20% higher daily doses were equivalent to the corresponding DR BID regimens with respect to exposure (AUC) while achieving lower maximum concentration (C(max)) and higher minimum concentration (C(min)) values. This was a Phase I, multiple-dose, fasting, randomized, open-label, crossover design study in healthy adult volunteers (n=36). The two crossover comparisons of unequal total daily doses were: 1000 mg ER versus 875 mg DR and 1500 mg ER versus 1250 mg DR. For each of 14 and 20% higher ER versus DR dose comparisons, the ER and DR regimens were equivalent with respect to AUC. Furthermore, the ER formulation achieved a lower C(max) central value and a higher C(min) mean than the corresponding values for the DR formulation. The mean peak-to-trough fluctuations of valproic acid plasma concentrations were 42-48% lower for the ER formulation compared with the DR. The higher ER doses were as well tolerated as DR, with a small number of adverse events that were non-serious in nature and mild in intensity. Therefore, increasing the once-daily ER dose 14-20% while converting from a total daily DR dose given twice-daily results in equivalent exposure with lower C(max) and higher C(min) values.