Evaluation of Dynamic Polar Molecular Surface Area as Predictor of Drug Absorption: Comparison with Other Computational and Experimental Predictors

Abstract

The relationship between various molecular descriptors and transport of drugs across the intestinal epithelium was evaluated. The monolayer permeability (P_c) of human intestinal Caco-2 cells to a series of nine β-receptor-blocking agents was investigated in vitro. The dynamic polar molecular surface area (PSA_d) of the compounds was calculated from all low-energy conformations identified in molecular mechanics calculations in vacuum and in simulated chloroform and water environments. For most of the investigated drugs, the effects of the different environments on PSA_d were small. The exception was H 216/44, which is a large flexible compound containing several functional groups capable of hydrogen bonding (PSA_d,chloroform = 70.8 Ų and PSA_d,water = 116.6 Ų). The relationship between P_c and PSA_d was stronger than those between P_c and the calculated octanol/water distribution coefficients (log D_calc) or the experimentally determined immobilized liposome chromatography (ILC) retention. P_c values for two new practolol analogues and H 216/44 were predicted from the structure−permeability relationships of a subset of the nine compounds and compared with experimental values. The P_c values of the two practolol analogues were predicted well from both PSA_d calculations and ILC retention studies. The P_c value of H 216/44 was reasonably well-predicted only from the PSA_d of conformations preferred in vacuum and in water. The other descriptors overestimated the P_c of H 216/44 100−500-fold.