Integrated oral bioavailability projection using in vitro screening data as a selection tool in drug discovery.

The objective of the analysis described herein is to examine the in vitro/in vivo relationship of estimated bioavailability values and also the applicability of the estimated in vitro bioavailability to lead candidate selection in drug discovery. To this end, in vitro ADME data from screening assays as well as in vivo rat pharmacokinetic (PK) data were compiled for 140 compounds across therapeutic areas from the Pfizer library in Ann Arbor. The compounds span a broad range of structural types, including neutral, basic, and acidic compounds. Solubility and Caco-2 permeability data from in vitro ADME screening were used to calculate the fraction dose absorbed (FDp) using the physiologically based IDEA model. In vitro metabolic stability (t(1/2)) from human and rat liver microsomal incubations was converted to an in vitro intrinsic clearance value (CL(int)'), which was then scaled up to reflect in vivo clearance (CL) and hepatic extraction as described by Obach et al. [J. Pharmcol. Exp. Ther. 283 (1997) 46]. Subsequently, the in vitro/in vivo relationship between the measured bioavailability (F(obs)) in rats and the estimated bioavailability (F(est)) from FDp and predicted CL values was examined. The observed data suggest that compounds with low estimated in vitro bioavailability (F(est)<15%) are more likely to have low in vivo bioavailability (F(obs)<30%). Therefore, the present study indicates that in vitro estimation of bioavailability is an efficient tool to eliminate compounds having low bioavailability prior to in vivo characterization and therefore can be used to reduce attrition due to poor ADME properties in drug development.

Enzyme-mediated precipitation of parent drugs from their phosphate prodrugs.

Many oral phosphate prodrugs have failed to improve the rate or extent of absorption compared to their insoluble parent drugs. Rapid parent drug generation via intestinal alkaline phosphatase can result in supersaturated solutions, leading to parent drug precipitation. The purpose was to (1) investigate whether parent drugs can precipitate from prodrug solutions in presence of alkaline phosphatase; (2) determine whether induction times are influenced by (a) dephosphorylation rate, (b) parent drug supersaturation level, and (c) parent drug solubility. Induction times were determined from increases in optical densities after enzyme addition to prodrug solutions of TAT-59, fosphenytoin and estramustine phosphate. Apparent supersaturation ratios (sigma) were calculated from parent drug solubility at intestinal pH. Precipitation could be generated for all three prodrugs. Induction times decreased with increased enzyme activity and supersaturation level and were within gastrointestinal residence times for TAT-59 concentration>/=21microM (sigma>/=210). Induction times for fosphenytoin were less than the GI residence time (199min) for concentrations of approximately 352 microM (sigma=4.0). At approximately 475 microM (sigma=5.3) the induction times were less than 90min. For estramustine-phosphate, no precipitation was observed within GI residence times. Enzyme-mediated precipitation will depend on apparent supersaturation ratios, parent drug dose, solubility and solubilization by the prodrug.

Absorption rate limit considerations for oral phosphate prodrugs.

PURPOSE: To evaluate the potential of phosphate ester prodrugs to significantly improve the absorptive flux of poorly soluble parent drugs. METHODS: Absorptive transport studies of parent drugs and their prodrugs were carried out in Caco-2 cells. Prodrugs of parent drugs with variable aqueous solubilities were tested: Hydrocortisone-phosphate/Hydrocortisone, Fosphenytoin/phenytoin, TAT-59/DP-TAT-59, and Entacapone phosphate/Entacapone. Additional absorption studies were carried out in rats. RESULTS: Absorptive fluxes of DP-TAT-59 and phenytoin increased 9.8 or 3.3-fold after dosing TAT-59 and 500 microM fosphenytoin, respectively. Hydrocortisone's flux did not increase with hydrocortisone-phosphate at 100 microM. Permeability of the highly lipophilic and protein bound compound, DP-TAT-59, was significantly increased with serosal albumin. No permeability increase was observed for the other drugs with albumin. Entacapone phosphate failed to improve the flux of entacapone compared to an entacapone solution, but the prodrug solution did yield higher entacapone plasma levels in rats when compared with an entacapone suspension. CONCLUSION: Ideal phosphate prodrug candidates are characterized by high permeability and low solubility (BCS Class II drugs). For low dose BCS Class II drug candidates, however, no biopharmaceutical advantage may be gained. Phosphate prodrugs of parent drugs with limited permeability may fail. When screening highly lipophilic parent drugs transport studies should be done with albumin.

Improved intestinal transport of PD 158473, an N-methyl-D-aspartate (NMDA) antagonist, by involvement of multiple transporters.

The objective of this research was to determine the characteristics of intestinal transport of PD 0158473 using in vitro Caco-2 cells as well as in situ single-pass rat intestinal perfusion models. Because apical (AP)-to-basolateral (BL) transport was greater (1.8- fold) than BL-to-AP transport in the Caco-2 cell model, identification of carrier system(s) involved was further investigated. Cellular uptake of PD 0158473 was concentration and/or pH dependent and significantly inhibited by substrates of dipeptide and monocarboxylic acid transporters. Although this compound is an analog of L-Phe and previous studies demonstrated a high affinity of this compound to large neutral amino acid transporter, the involvement of amino acid carriers did not appear to be significant in the Caco-2 cell model. Subsequently, in situ single-pass intestinal perfusion studies in rats demonstrated that intestinal absorption of PD 0158473 was not concentration dependent at a concentration range tested but significantly inhibited by various dipeptides as well as substrates of dipeptide transporters. The difference in the concentration-dependent transport of PD 0158473 between Caco-2 cells and the rat perfusion model could be explained by the difference in the affinity (apparent K(m)) of PD 0158473 between Caco-2 cells (107 microM) and rat tissue (>1 mM). The present study suggested that multiple transporters are involved in the transcellular transport of this amino-acid analogue compound, of which peptide transporters could play a major role.