D.F. McGinnity, J. Collington, R.P. Austin and R.J. Riley Pages 463 - 479 ( 17 )
In this article approaches to predict human pharmacokinetics (PK) are discussed and the capability of the exemplified methodologies to estimate individual PK parameters and therapeutic dose for a set of marketed oral drugs has been assessed. For a set of 63 drugs where the minimum efficacious concentration (MEC) and human PK were known, the clinical dose was shown to be well predicted or in some cases over-estimated using a simple one-compartment oral PK model. For a subset of these drugs, in vitro potency against the primary human targets was gathered, and compared to the observed MEC. When corrected for plasma protein binding, the MEC of the majority of compounds was 3 fold over the respective in vitro target potency value. A series of in vitro and in vivo experiments were conducted to predict the human PK parameters. Metabolic clearance was generally predicted well from human hepatocytes. Interestingly, for this compound set, allometry or glomerular filtration rate (GFR) ratio methods appeared to be applicable for renal CL even where CLrenal > GFR. For ∼90% of compounds studied, the predicted CL using in vitro-in vivo (IVIV) extrapolation together with a CLrenal estimate, where appropriate, was within 2-fold of that observed clinically. Encouragingly volume of distribution at steady state (Vss) estimated in preclinical species (rat and dog) when corrected for plasma protein binding, predicted human Vss successfully on the majority of occasions - 73% of compounds within 2-fold. In this laboratory, absorption estimated from oral rat PK studies was lower than the observed human absorption for most drugs, even when solubility and permeability appeared not to be limiting. Preliminary data indicate absorption in the dog may be more representative of human for compounds absorbed via the transcellular pathway. Using predicted PK and MEC values estimated from in vitro potency assays there was a good correlation between predicted and observed dose. This analysis suggests that for oral therapies, human PK parameters and clinical dose can be estimated from a consideration of data obtained from in vitro screens using human derived material and in vivo animal studies. The benefits and limitations of this holistic approach to PK and dose prediction within the drug discovery process are exemplified and discussed.
Mechanism-based inactivation, Drug-Drug Interactions, In vitro-in vivo Extrapolation, DDI Risk Assessment
Department of Physical&Metabolic Science, AstraZeneca R Charnwood, Bakewell Road, Loughborough,Leicestershire. LE11 5RH, UK.