A Cross-study Analysis of Drug Response Prediction in Cancer Cell Lines

Overview

Journal Brief Bioinform

Publisher Oxford University Press

Specialty Biology

Date 2021 Sep 15

PMID 34524425

Citations 27

Authors

Fangfang Xia

Jonathan Allen

Prasanna Balaprakash

Thomas Brettin

Cristina Garcia-Cardona

Austin Clyde

Judith Cohn

James Doroshow

Xiaotian Duan

Veronika Dubinkina

Yvonne Evrard

Ya Ju Fan

Jason Gans

Stewart He

Pinyi Lu

Sergei Maslov

Alexander Partin

Maulik Shukla

Eric Stahlberg

Justin M Wozniak

Hyunseung Yoo

George Zaki

Yitan Zhu

Rick Stevens

Affiliations

Soon will be listed here.

Abstract

To enable personalized cancer treatment, machine learning models have been developed to predict drug response as a function of tumor and drug features. However, most algorithm development efforts have relied on cross-validation within a single study to assess model accuracy. While an essential first step, cross-validation within a biological data set typically provides an overly optimistic estimate of the prediction performance on independent test sets. To provide a more rigorous assessment of model generalizability between different studies, we use machine learning to analyze five publicly available cell line-based data sets: National Cancer Institute 60, ancer Therapeutics Response Portal (CTRP), Genomics of Drug Sensitivity in Cancer, Cancer Cell Line Encyclopedia and Genentech Cell Line Screening Initiative (gCSI). Based on observed experimental variability across studies, we explore estimates of prediction upper bounds. We report performance results of a variety of machine learning models, with a multitasking deep neural network achieving the best cross-study generalizability. By multiple measures, models trained on CTRP yield the most accurate predictions on the remaining testing data, and gCSI is the most predictable among the cell line data sets included in this study. With these experiments and further simulations on partial data, two lessons emerge: (1) differences in viability assays can limit model generalizability across studies and (2) drug diversity, more than tumor diversity, is crucial for raising model generalizability in preclinical screening.

Citing Articles

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