Abstract
To assess the ability of a previously developed hybrid physiology-based pharmacokinetic-pharmacodynamic (PBPKPD) model in rats to predict the dopamine D2 receptor occupancy (D2RO) in human striatum following administration of antipsychotic drugs. A hybrid PBPKPD model, previously developed using information on plasma concentrations, brain exposure and D2RO in rats, was used as the basis for the prediction of D2RO in human. The rat pharmacokinetic and brain physiology parameters were substituted with human population pharmacokinetic parameters and human physiological information. To predict the passive transport across the human blood-brain barrier, apparent permeability values were scaled based on rat and human brain endothelial surface area. Active efflux clearance in brain was scaled from rat to human using both human brain endothelial surface area and MDR1 expression. Binding constants at the D2 receptor were scaled based on the differences between in vitro and in vivo systems of the same species. The predictive power of this physiology-based approach was determined by comparing the D2RO predictions with the observed human D2RO of six antipsychotics at clinically relevant doses. Predicted human D2RO was in good agreement with clinically observed D2RO for five antipsychotics. Models using in vitro information predicted human D2RO well for most of the compounds evaluated in this analysis. However, human D2RO was under-predicted for haloperidol. The rat hybrid PBPKPD model structure, integrated with in vitro information and human pharmacokinetic and physiological information, constitutes a scientific basis to predict the time course of D2RO in man.
Highlights
In schizophrenia drug therapy and research, dopamine D2 receptor occupancy (D2RO) is often used as a target biomarker to quantify the relationship between efficacy and side effects [1]
Several studies suggest that blockade of 65 to 80% of D2 receptors is the key to antipsychotic efficacy for both conventional neuroleptics and novel antipsychotics [2,3,4]
For risperidone (RIS), human D2RO was provided from the pharmaceutical companies who are involved in this project
Summary
In schizophrenia drug therapy and research, dopamine D2 receptor occupancy (D2RO) is often used as a target biomarker to quantify the relationship between efficacy and side effects [1]. D2RO has a central role in antipsychotic drug discovery, drug development and therapy. Tools to predict clinical D2RO in preclinical drug discovery phases are valuable. It is well known that current antipsychotics activate or antagonize other targets in the central nervous system. Risperidone has a higher affinity for serotonin (5HT2A) receptors than for D2 receptors [5]. Extensions of this tool to other receptors would increase the value of the current translation framework
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