Nonspecific binding to microsomes: impact on scale-up of in vitro intrinsic clearance to hepatic clearance as assessed through examination of warfarin, imipramine, and propranolol.

The nonspecific, noncovalent binding of three drugs, imipramine, warfarin, and propranolol, to pooled human and animal liver microsomes has been determined using equilibrium dialysis in conditions where no cofactor (NADPH) was included in the incubation. The binding of warfarin was dependent upon both protein and drug concentration, whereas the binding of propranolol and imipramine was also dependent upon protein concentration but generally independent of drug concentration. At a microsomal protein concentration of 1.0 mg/ml and a warfarin concentration of 10 microM, the free fraction (fu(mic)) was 0.85. The corresponding values for propranolol and imipramine were 0.41 and 0.16, respectively. Thus, although all three drugs exhibit high binding in plasma (fu<0.1) the acidic drug warfarin differs from the basic drugs propranolol and imipramine in the extent to which each binds to microsomal protein. The binding of all three drugs to liver microsomes obtained from commonly studied animal species (rat, dog, and monkey) was almost identical to that observed in human. Additionally, the binding of warfarin and propranolol to microsomes obtained from insect cells used in baculovirus cytochrome P450 expression systems was similar to that exhibited in liver microsomes, when equal protein concentrations were compared. The enzyme kinetics of propranolol, imipramine, and warfarin oxidative metabolism were determined in pooled human liver microsomes, and the intrinsic clearance values obtained were used in scaling up to project human in vivo clearance. The values obtained by incorporating microsomal binding were compared with those in which this factor is ignored. The findings suggest that the parameter fu(mic) is important to obtain when attempting to relate in vitro intrinsic clearance to in vivo clearance. Also, this value is important to consider when comparing substrates with respect to enzyme specificity, since measured apparent KM values should be converted to true "free KM" values by correcting for the free fraction in the in vitro incubation. Furthermore, the extent of nonspecific binding to microsomes is likely an important parameter to consider when attempting to relate Ki values measured in vitro to observations of drug-drug interactions (or the lack thereof) in vivo.