In vitro-in vivo relationship of oral extended-release dosage forms

In vitro and in vivo evaluation of single-unit commercial conventional tablet and sustained-release capsules compared with multiple-unit polystyrene microparticle dosage forms of Ibuprofen

The major aims of the present study were (1) to select a multiple-unit formulation that matched the in vitro dissolution profile of single-unit sustained-release commercial capsules, (2) to compare the sustaining/controlling efficacy of the selected multiple-unit formulation with that of the single-unit commercial conventional tablet and sustained-release capsules, and (3) to determine whether an in vitro-in vivo correlation exists for single- and multiple-unit formulations. Ibuprofen (20%-60% wt/wt)-loaded multiple-unit polystyrene microparticles were prepared by an emulsion-solvent evaporation method from an aqueous system. The in vitro release profiles obtained in phosphate buffer of pH 6.8 for drug-loaded polystyrene microparticles and for commercial sustained-release capsules (Fenlong-SR, 400 mg) were compared. Since the microparticles with 30% ibuprofen load showed a release profile comparable to that of the Fenlong-SR release profile, the microparticles with this drug load were considered to be the optimized/selected formulation and, therefore, were subjected to stability study and in vivo study in human volunteers. A single-dose oral bioavailability study revealed significant differences in C(max), T(max), t(1/2a), t(1/2e), K(a), K(e), and AUC between the conventional tablet and optimized or Fenlong-SR capsule dosage forms. However, all the parameters, with the exception of K(a) along with relative bioavailability (F) and retard quotient (R(Delta)), obtained from the optimized ibuprofen-loaded microparticles were lower than that obtained from the commercial Fenlong-SR formulation. Furthermore, linear relationship obtained between the percentages dissolved and absorbed suggests a means to predict in vivo absorption by measuring in vitro dissolution.

Optimization of sustained-release diltiazem formulations in man by use of an in-vitro/in-vivo correlation

In-vitro/in-vivo correlations (IVIVC) are useful for predicting in-vivo results from in-vitro data. An IVIVC has been used to optimize a hydrocolloidal-based matrix tablet designed to be bioequivalent to an existing once-daily diltiazem HC1 product (Dilacor XR 240mg; Rhone-Poulenc Rorer). Data from a preliminary formulation dosed to fasted and fed subjects were used to establish the IVIVC. The correlation was then used during reformulation of the dosage forms to predict changes in the maximum plasma concentration (Cmax) and the area under the plasma-concentration-time curve (AUC) for fasted and fed subjects using in-vitro dissolution data. The IVIVC adequately predicted plasma profiles of two optimized formulations in studies with fasted and fed subjects.

Analysis of metabolite kinetics by deconvolution and in vivo-in vitro correlations of metabolite formation rates: studies of fibrinogen receptor antagonist ester prodrugs

The pharmacokinetics of L-767,679, a potent fibrinogen receptor antagonist, were characterized following administration of its ethyl ester prodrug to dogs and monkeys. Deconvolution analysis was performed to determine the rate and extent of (1) the formation of L-767,679 from the prodrug in the systemic circulation, (2) the composite input (systemic and presystemic) of L-767,679 to the general circulation after oral administration of the prodrug, (3) the oral input of the prodrug, and (4) the input of the presystemically formed L-767,679 following oral administration of the prodrug. The results indicated that there were species differences in the kinetics of the disposition of L-767,679 and its prodrug. In dogs, the prodrug was absorbed faster than it was converted to the active drug, and the presystemic formation of L-767,679 contributed to about one-half of the total input of L-767,679 following oral administration of the prodrug. In monkeys, the low input of L-767,679 following oral administration of the prodrug was not due to an inefficient formation of L-767,679 in the systemic circulation but rather to the low oral bioavailability of the prodrug. Virtually all of the total oral input of L-767,679 following administration of its prodrug to monkeys resulted from the presystemic metabolism of the prodrug. These results were consistent with the finding in monkeys that the ester prodrug underwent extensive transformation to metabolites other than L-767,679. In addition, the present study also demonstrated a correlation between in vivo formation rates of L-767,679 determined using deconvolution analysis following its ethyl, methyl, and isopropyl esters in dogs and the ethyl ester in monkeys and in vitro formation rates of L-767,679 obtained following incubations of the corresponding esters with dog and monkey liver microsomes. The results suggested that deconvolution and/or convolution analysis together with in vitro metabolism results could potentially be used to predict in vivo formation rates of other ester prodrugs of L-767,679 and also plasma concentrations of L-767,679 as a function of time, following administration of its prodrugs.