Dealing with Time-dependent Pharmacokinetics During the Early Clinical Development of a New Leukotriene B4 Synthesis Inhibitor

Overview

Journal Pharm Res

Specialties Pharmacology
Pharmacy

Date 2006 Jun 20

PMID 16783479

Citations 6

Authors

Inaki F Troconiz

Ilonka Zsolt

Maria J Garrido

Marta Valle

Rosa M Antonijoan

Manel J Barbanoj

Affiliations

Soon will be listed here.

Abstract

Purpose: The aim of this study was to explore the possibility of achieving a practical dosing regimen for 2,4,6-triiodophenol (AM-24), a new leukotriene B4 (LTB4) synthesis inhibitor. First, a model capable of dealing with the nonlinearity in its pharmacokinetic profile was built, and then it was combined with a pharmacodynamic model previously established with data from earlier phase I trials.

Methods: One week after the first 240-, 350-, or 500-mg oral dose of AM-24, six additional doses were given to 24 healthy volunteers once daily. A total of 33 blood samples were obtained from each individual. Different models, including enzyme turnover models, were fitted to the data by using the software NONMEM.

Results: Drug absorption was modeled with a first-order process. Drug disposition was described with a one-compartment model, and elimination with an (auto)inhibited and a noninhibited clearance. AM-24 inhibited the enzyme production rate to a maximum of 98%. Relative bioavailability was independent of the decrease in the amount of enzyme. The estimate of the enzyme turnover half-life was 8.5 h.

Conclusions: Simulations have shown that steady-state conditions eliciting 90% of maximal LTB4 synthesis inhibition can be reached after 3 weeks during an oral treatment with AM-24 administered at the dosage of 500 mg once daily.

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