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DTF: Deep Tensor Factorization for Predicting Anticancer Drug Synergy

Quantitative Methods 2020-09-17 v7

Abstract

Motivation: Combination therapies have been widely used to treat cancers. However, it is cost- and time-consuming to experimentally screen synergistic drug pairs due to the enormous number of possible drug combinations. Thus, computational methods have become an important way to predict and prioritize synergistic drug pairs. Results: We proposed a Deep Tensor Factorization (DTF) model, which integrated a tensor factorization method and a deep neural network (DNN), to predict drug synergy. The former extracts latent features from drug synergy information while the latter constructs a binary classifier to predict the drug synergy status. Compared to the tensor-based method, the DTF model performed better in predicting drug synergy. The area under the precision-recall curve (PR AUC) was 0.57 for DTF and 0.24 for the tensor method. We also compared the DTF model with DeepSynergy and logistic regression models and found that the DTF outperformed the logistic regression model and achieved almost the same performance as DeepSynergy using several typical metrics for the classification task. Applying the DTF model to predict missing entries in our drug-cell line tensor, we identified novel synergistic drug combinations for 10 cell lines from the 5 cancer types. A literature survey showed that some of these predicted drug synergies have been identified in vivo or in vitro. Thus, the DTF model could be valuable in silico tool for prioritizing novel synergistic drug combinations.

Keywords

Cite

@article{arxiv.1911.10313,
  title  = {DTF: Deep Tensor Factorization for Predicting Anticancer Drug Synergy},
  author = {Zexuan Sun and Shujun Huang and Peiran Jiang and Pingzhao Hu},
  journal= {arXiv preprint arXiv:1911.10313},
  year   = {2020}
}

Comments

Final draft in Bioinformatics, btaa287, https://doi.org/10.1093/bioinformatics/btaa287

R2 v1 2026-06-23T12:25:05.364Z