Application of empirical scalars to enable early prediction of human hepatic clearance using IVIVE in drug discovery: an evaluation of 173 drugs

Robert S Jones; Christian Leung; Jae H Chang; Suzanne Brown; Ning Liu; Zhengyin Yan; Jane R Kenny; Fabio Broccatelli

doi:10.1124/dmd.121.000784

Application of empirical scalars to enable early prediction of human hepatic clearance using IVIVE in drug discovery: an evaluation of 173 drugs

Drug Metab Dispos. 2022 May 30:DMD-AR-2021-000784. doi: 10.1124/dmd.121.000784. Online ahead of print.

Authors

Robert S Jones¹, Christian Leung², Jae H Chang³, Suzanne Brown⁴, Ning Liu⁵, Zhengyin Yan⁶, Jane R Kenny⁷, Fabio Broccatelli²

Affiliations

¹ Genentech, Inc, United States jones.robert@gene.com.
² Genentech, United States.
³ Preclinical Development Sciences, ORIC Pharmaceuticals, United States.
⁴ Ultragenyx Pharmaceutical, United States.
⁵ Avirmax, Inc., United States.
⁶ DMPK, Genentech INC, United States.
⁷ Drug Metabolism & Pharmacokinetics, Genentech Inc, United States.

PMID: 35636770
DOI: 10.1124/dmd.121.000784

Abstract

The utilization of in vitro data to predict drug pharmacokinetics (PK) in vivo has been a consistent practice in early drug discovery for decades. However, its success is hampered by mispredictions attributed to uncharacterized biological phenomena/experimental artifacts. Predicted drug clearance (CL) from experimental data (i.e. hepatocyte intrinsic clearance: CL_int, fraction unbound in plasma: f_u,p) is often systematically underpredicted using the well-stirred model (WSM). The objective of this study was to evaluate using empirical scalars in the WSM to correct for CL mispredictions. Drugs (N=28) were used to generate numerical scalars on CL_int (α), and f_u,p (β) to minimize the error (AAFE) for CL predictions. These scalars were validated using an additional dataset (N=28 drugs) and applied to a non-redundant AstraZeneca (AZ) dataset available in the literature (N=117 drugs) for a total of 173 compounds. CL predictions using the WSM were improved for most compounds using an α value of 3.66 (~64%<2-fold) compared to no scaling (~46%<2-fold). Similarly, using a β value of 0.55 or combination of α and β scalars (values of 1.74 and 0.66, respectively) resulted in a similar improvement in predictions (~64%<2-fold and ~65%<2-fold, respectively). For highly bound compounds (f_u,p{less than or equal to}0.01), AAFE was substantially reduced across all scaling methods. Using the β scalar alone or a combination of α and β appeared optimal; and produce larger magnitude corrections for highly-bound compounds. Some drugs are still disproportionally mispredicted, however the improvements in prediction error and simplicity of applying these scalars suggests its utility for early-stage CL predictions. Significance Statement In early drug discovery, prediction of human clearance using in vitro experimental data plays an essential role in triaging compounds prior to in vivo studies. These predictions have been systematically underestimated. Here we introduce empirical scalars calibrated on the extent of plasma protein binding that appear to improve clearance prediction across multiple datasets. This approach can be used in early phases of drug discovery prior to the availability of pre-clinical data for early quantitative predictions of human clearance.

Keywords: drug clearance; hepatic elimination; in vitro-in vivo prediction (IVIVE); in vitro-in vivo scaling; plasma protein binding.