Challenges and Opportunities for In Vitro–In Vivo Extrapolation of Aldehyde Oxidase-Mediated Clearance: Toward a Roadmap for Quantitative Translation
Nihan Izat, Jayaprakasam Bolleddula, Armina Abbasi, Lionel Cheruzel, Robert S. Jones, Darren Moss, Fátima Ortega-Muro, Yannick Parmentier, Vincent Peterkin, Dandan Tian, Karthik Venkatakrishnan, Michael Zientek, Jill Barber, J. Brian Houston, Aleksandra Galetin, Daniel Scotcher
Abstract
Underestimation of AO-mediated clearance by current <i>in vitro</i> assays leads to uncertainty in human dose projections, thereby reducing the likelihood of success in drug development. In the present study we first evaluated the current drug development practices for AO substrates. Next, the overall predictive performance of <i>in vitro-in vivo</i> extrapolation (IVIVE) of unbound hepatic intrinsic clearance (CL<sub>int,u</sub>) and unbound hepatic intrinsic clearance by AO (CL<sub>int,u,AO</sub>) was assessed using a comprehensive literature database of <i>in vitro</i> (human cytosol/ S9/ hepatocytes) and <i>in vivo</i> (iv/oral) data collated for 22 AO substrates (total of 100 datapoints from multiple studies). Correction for unbound fraction in the incubation (fu<sub>inc</sub>) was done by experimental data or <i>in silico</i> predictions. The fraction metabolized by AO (fm<sub>AO</sub>) determined via <i>in vitro/in vivo</i> approaches was found to be highly variable. The geometric mean fold errors (gmfe) for scaled CL<sub>int,u </sub>(mL/min/kg) were 10.4 for human hepatocytes, 5.6 for human liver cytosols, and 5.0 for human liver S9, respectively. Application of these gmfe9s as empirical scaling factors improved predictions (45-57% within 2-fold of observed) compared with no correction (11-27% within 2-fold), with the scaling factors qualified by leave-one-out cross-validation. A road map for quantitative translation was then proposed following a critical evaluation on the <i>i</i><i>n vitro </i>and clinical methodology to estimate<i> in vivo</i> fm<sub>AO</sub>. In conclusion, the study provides the most robust system-specific empirical scaling factors to-date as a pragmatic approach for the prediction of <i>in vivo</i> CL<sub>int,u,AO</sub> in the early stages of drug development. <b>Significance Statement</b> Confidence remains low when predicting <i>in vivo</i> clearance of aldehyde oxidase (AO) substrates using <i>in vitro</i> systems, leading to de-prioritisation of AO substrates from the drug development pipeline to mitigate risk of unexpected and costly <i>in vivo</i> impact. The current study establishes a set of empirical scaling factors as a pragmatic tool to improve predictability of <i>in vivo</i> AO clearance. Developing clinical pharmacology strategies for AO substrates by utilizing mass balance/clinical DDI data will help build confidence in fm<sub>AO</sub>.