CRADLE-VAE: Enhancing Single-Cell Gene Perturbation Modeling with Counterfactual Reasoning-based Artifact Disentanglement

Seungheun Baek, Soyon Park, Yan Ting Chok, Junhyun Lee, Jueon Park, Mogan Gim, Jaewoo Kang
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Abstract

Predicting cellular responses to various perturbations is a critical focus in drug discovery and personalized therapeutics, with deep learning models playing a significant role in this endeavor. Single-cell datasets contain technical artifacts that may hinder the predictability of such models, which poses quality control issues highly regarded in this area. To address this, we propose CRADLE-VAE, a causal generative framework tailored for single-cell gene perturbation modeling, enhanced with counterfactual reasoning-based artifact disentanglement. Throughout training, CRADLE-VAE models the underlying latent distribution of technical artifacts and perturbation effects present in single-cell datasets. It employs counterfactual reasoning to effectively disentangle such artifacts by modulating the latent basal spaces and learns robust features for generating cellular response data with improved quality. Experimental results demonstrate that this approach improves not only treatment effect estimation performance but also generative quality as well. The CRADLE-VAE codebase is publicly available at https://github.com/dmis-lab/CRADLE-VAE.
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CRADLE-VAE:利用基于反事实推理的伪差解除增强单细胞基因扰动建模
预测细胞对各种扰动的反应是药物发现和个性化治疗的一个关键重点,深度学习模型在这方面发挥着重要作用。单细胞数据集包含的技术因素可能会阻碍此类模型的可预测性,这就带来了该领域备受关注的质量控制问题。为了解决这个问题,我们提出了 CRADLE-VAE,这是一个为单细胞基因扰动建模量身定制的因果生成框架,并通过基于反事实推理的人工制品解纠缠功能进行了增强。在整个训练过程中,CRADLE-VAE 对单细胞数据集中存在的技术假象和扰动效应的潜在分布进行建模。实验结果表明,这种方法不仅能提高治疗效果估计性能,还能提高生成质量。CRADLE-VAE代码库可在https://github.com/dmis-lab/CRADLE-VAE。
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