Cirrhosis does not affect the pharmacokinetics and pharmacodynamics of clopidogrel.

Clopidogrel, a new platelet ADP receptor antagonist used for the prevention of vascular ischemic events, is converted to an active metabolite via the cytochrome P450 system. Patients with cirrhosis may not metabolize drugs normally and may, in addition, have a number of defects in the coagulation system. To assess the effect of cirrhosis on the pharmacokinetics and pharmacodynamics of clopidogrel, the authors performed an open-label, parallel-group study of 12 patients with Child-Pugh Class A or B cirrhosis and 12 matched controls. All 24 subjects received clopidogrel 75 mg PO QD for 10 days. Pharmacokinetics of clopidogrel and the major metabolite SR 26334 were analyzed on Days 1 and 10; pharmacodynamics were assessed by the inhibition of ADP-induced platelet aggregation and by bleeding time prolongation factor. Pharmacokinetic analysis of clopidogrel was limited due to low plasma concentrations arising from rapid hydrolysis to SR 26334. The Cmax at SS for clopidogrel was higher in cirrhotics than in normals. However, exposures to the metabolite SR 26334, as measured by AUC(tau), were comparable. At Day 10, there was not a statistically significant difference in mean inhibition of platelet aggregation (49.2% +/- 38.6% in cirrhotics vs. 66.7% +/- 7.5% in normals) or in bleeding time prolongation factor (1.64 +/- 0.49 in cirrhotics vs. 1.54 +/- 0.87 in normals) between groups. No significant adverse events, including bleeding events, were reported. In conclusion, there were no significant differences in the pharmacokinetics and pharmacodynamics of clopidogrel in this group of subjects with cirrhosis and matched normals. Therefore, no dosage adjustment of clopidogrel is required in patients with Child-Pugh Class A or B cirrhosis.

Estimation of oral bioavailability of a long half-life drug in healthy subjects.

PURPOSE: To estimate and compare the oral bioavailability of a drug (BMS-187745) administered as single doses of oral solution of either the parent drug or its prodrug (BMS-188494). METHODS: A single-dose, two-period, three-treatment, control-balanced, residual-effect, incomplete block crossover study was completed in 16 healthy male subjects. All subjects received a 10 mg IV infusion of BMS-187745, and a single oral dose of either BMS-187745 (PO1) or BMS-188494 (PO2). A model is proposed to calculate the oral bioavailability of BMS-187745 which has a long half-life; incomplete data points were available to characterize its elimination phase. The plasma concentration-time data obtained following IV infusion of parent drug, and after administration of either PO1 or PO2 treatment were fitted simultaneously with systemic pharmacokinetic parameters shared by both the oral and IV routes of administration. RESULTS: The best simultaneous fittings of the plasma concentration-time data were obtained by using a biexponential pharmacokinetic model with a first-order absorption rate constant. The mean bioavailability (F) values of BMS- 187745 estimated by the proposed model were 26.5% and 2.6% when given as oral solution of its prodrug and as the parent drug. The coefficient of variation (CV) of these F values are reasonable, ranging from 38-40%. In contrast, F calculated by the model-independent AUC method exhibited high CV, ranging from 111-120%. CONCLUSIONS: The oral bioavailability values estimated by the proposed model were more reasonable compared to those calculated by the model-independent AUC method. The proposed approach may be useful for estimating bioavailability of long half-life drugs when incomplete data points are available to characterize their elimination phase.

Clinical pharmacokinetics and pharmacodynamics of a new squalene synthase inhibitor, BMS-188494, in healthy volunteers.

A double-blind, placebo-controlled, parallel-group, ascending, multiple-dose study was completed in 45 healthy male volunteers to assess the maximum tolerated dose, pharmacokinetics, and pharmacodynamics of BMS-187745, a squalene synthase inhibitor, administered as multiple oral doses of its prodrug BMS-188494. Participants received a daily oral dose of 10 mg for 2 weeks, or a daily oral dose of 25, 50, 100, or 200 mg for 4 weeks. The absorption rate constant (ka) and bioavailability (F) values were estimated by fitting the plasma BMS-187745 concentration-time data to a biexponential function with a first-order ka. Values for F were similar for all five dose levels, and thus were independent of dose. The ka values also were similar for all dose groups except the 50-mg group, for which ka values were somewhat higher. The change in urinary excretion rate of farnesyl pyrophosphate metabolite (dioic acid) was determined to be a pharmacodynamic measure. There was no significant change in dioic acid excretion at doses of less than 100 mg given for 4 weeks. An indirect pharmacodynamic response model with threshold concentration (CT) and based on inhibition of squalene synthase was proposed to describe the effect versus time data. The pharmacodynamic data from all dose levels were fitted simultaneously to the proposed model and the fitted parameters estimated as CT = 3.9 micrograms/mL, kout = 0.47 hr-1, IC50 = 4.1 micrograms/mL, and Imax = 1.0. The proposed indirect response model requiring a threshold concentration provides a useful means of quantitating responses for a new type of therapeutic agent.

The pharmacokinetics of pravastatin in patients on chronic hemodialysis.

OBJECTIVE: The single-dose and steady-state pharmacokinetics of the HMG CoA reductase inhibitor pravastatin and its two metabolites, SQ 31,906 and SQ 31,945, were evaluated in 12 hemodialysis patients. A single 20-mg i.v. dose was employed, followed by daily oral dosing of 20 mg over four hemodialysis intervals. RESULTS: No statistical differences in the pharmacokinetics of pravastatin or SQ 31,906 were evident when comparing the first and last days of oral dosing with pravastatin. The pharmacokinetic parameters of pravastatin and SQ 31,906 were similar to those of healthy volunteers. SQ 31,945, the inactive polar metabolite, did accumulate in dialysis patients, as evidenced by an accumulation index of 1.7 +/- 1.0. Although metabolic clearance is the predominant mode of elimination of pravastatin, hemodialysis clearances of pravastatin, SQ 31,906 and SQ 31,945 will contribute to total body clearance since dialytic clearance ranged from 40 to 80 ml.min-1. CONCLUSION: Pravastatin can be safely administered in the usual dosages to subjects with renal failure on hemodialysis and no change in dosing is necessary.

A pharmacokinetic-pharmacodynamic model of d-sotalol Q-Tc prolongation during intravenous administration to healthy subjects.

The objective of this study was to assess the pharmacokinetics and pharmacodynamics of the dextro (d-) isomer of sotalol, a class III antiarrhythmic agent, in healthy young men and women after a single intravenous bolus dose. The design was open-label, randomized, parallel group. Each group (4 men and 4 women) received either 0.5, 1.5, or 3.0 mg/kg d-sotalol as an intravenous infusion for 2 minutes. Serial measurements of the d-sotalol plasma concentration and the Q-Tc interval data were recorded before, during, and for 72 hours after drug administration. The pharmacokinetics of d-sotalol were found to be well described by a three-compartment model with linear elimination clearance from the central compartment. There were no significant differences in the elimination clearance or volume of the central compartment between dose levels or between men and women. However, women were found to have a lower steady-state volume of distribution than men (1.20 L/Kg versus 1.43 L/Kg). The Q-Tc versus d-sotalol plasma concentration data were fitted to a model that assumed a distinct "effect compartment" and sigmoidal Emax response. The baseline Q-Tc, determined from the fittings, was found to be significantly higher in women (0.40 versus 0.38 seconds). The effect compartment clearance was found to be highly variable, with a median of 12.3 (range, 0.2-671,300) L/h. There were statistically significant differences in the effect compartment clearance by dose among men and by gender at a dose of 1.5 mg/kg. There were no significant differences detected between dose groups or genders for the d-sotalol effect site concentration at one half the maximum Q-Tc prolongation from baseline (EC50), EMAX, (the maximum Q-Tc prolongation from baseline) or the Hill coefficient. In conclusion, the pharmacokinetics of d-sotalol after intravenous administration are independent of dose and gender, because the difference between men and women in volume of distribution at steady-state is not clinically significant. The pharmacodynamics of Q-Tc prolongation produced by d-sotalol appear to be independent of dose and gender; however, there is considerable variability in the time course of effects on Q-Tc between individuals.

Ranitidine pharmacokinetics and adverse central nervous system reactions.

BACKGROUND: Treatment with histamine2-receptor antagonists has been associated with adverse central nervous system reactions (CNS-ADRs). Previous studies of cimetidine have shown an association between CNS-ADRs and high cimetidine drug levels. While case reports of ranitidine CNS-ADRs have appeared, we wanted to study a series of patients, some of whom were critically ill, for the presence of CNS-ADRs and to correlate these with ranitidine pharmacokinetics. METHODS: A prospective, observational, open study included 163 consecutive patients, of whom 41 met entry criteria. A nonlinear least-squares regression analysis was used to establish a ranitidine pharmacokinetic dosing model. Ranitidine levels were determined by a high-performance liquid chromatographic assay. Individual ranitidine pharmacokinetics were determined by means of a bayesian model. Observations on 13 possible CNS-ADRs were recorded. The CNS-ADRs were evaluated by the Naranjo rating system. RESULTS: Ranitidine-associated CNS-ADRs, particularly lethargy, confusion, somnolence, and disorientation, occurred more frequently in patients with renal function impairment, and these were associated with higher peak concentrations, average plasma concentrations, and area under the curve. CONCLUSIONS: Ranitidine, when given in conventional doses, can cause CNS-ADRs, particularly in older patients who have substantial renal function impairment. These CNS-ADRs occur as a consequence of altered ranitidine disposition. Ranitidine doses should be reduced when renal function impairment is present, and patients should be carefully observed for CNS-ADRs.

Listeria monocytogenes endocarditis on a prosthetic heart valve.

Listeria monocytogenes endocarditis, an illness with a potentially high mortality developed in a patient with a porcine mitral valve heterograft. After treatment with parenteral ampicillin and streptomycin, blood cultures remained sterile and vegetations noted before treatment cleared. Delay in diagnosis and institution of appropriate antimicrobial therapy may occur because of the diverse morphologic features of L monocytogenes.