Influencing factors on false positive rates when classifying tumor cell line response to drug treatment

Informed selection of drug candidates for laboratory experimentation provides an efficient means of identifying suitable anti-cancer treatments. The advancement of artificial intelligence has led to the development of computational models to predict cancer cell line response to drug treatment. It is important to analyze the false positive rate (FPR) of the models, to increase the number of effective treatments identified and to minimize unnecessary laboratory experimentation. Such analysis will also aid in identifying drugs or cancer types that require more data collection to improve model predictions. This work uses an attention based neural network classification model to identify responsive/non-responsive drug treatments across multiple types of cancer cell lines. Two data filtering techniques have been applied to generate 10 data subsets, including removing samples for which dose response curves are poorly fitted and removing samples whose area under the dose response curve (AUC) values are marginal around 0.5 from the training set. One hundred trials of 10-fold cross-validation analysis is performed to test the model prediction performance on all the data subsets and the subset with the best model prediction performance is selected for further analysis. Several error analysis metrics such as the false positive rate (FPR), and the prediction uncertainty are evaluated, and the results are summarized by cancer type and drug mechanism of action (MoA) category. The FPR of cancer type spans between 0.262 and 0.5189, while that of drug MoA category spans almost the full range of [0, 1]. This study identifies cancer types and drug MoAs with high FPRs. Additional drug screening data of these cancer and drug categories may improve response modeling. Our results also demonstrate that the two data filtering approaches help improve the drug response prediction performance.