Automated Discovery of Pairwise Interactions from Unstructured Data

arXiv - STAT - Machine Learning Pub Date : 2024-09-11 DOI:arxiv-2409.07594

ZuhengDavid, Xu, Moksh Jain, Ali Denton, Shawn Whitfield, Aniket Didolkar, Berton Earnshaw, Jason Hartford

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Abstract

Pairwise interactions between perturbations to a system can provide evidence for the causal dependencies of the underlying underlying mechanisms of a system. When observations are low dimensional, hand crafted measurements, detecting interactions amounts to simple statistical tests, but it is not obvious how to detect interactions between perturbations affecting latent variables. We derive two interaction tests that are based on pairwise interventions, and show how these tests can be integrated into an active learning pipeline to efficiently discover pairwise interactions between perturbations. We illustrate the value of these tests in the context of biology, where pairwise perturbation experiments are frequently used to reveal interactions that are not observable from any single perturbation. Our tests can be run on unstructured data, such as the pixels in an image, which enables a more general notion of interaction than typical cell viability experiments, and can be run on cheaper experimental assays. We validate on several synthetic and real biological experiments that our tests are able to identify interacting pairs effectively. We evaluate our approach on a real biological experiment where we knocked out 50 pairs of genes and measured the effect with microscopy images. We show that we are able to recover significantly more known biological interactions than random search and standard active learning baselines.

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从非结构化数据中自动发现配对交互作用

系统扰动之间的成对交互作用可以为系统潜在机制的因果关系提供证据。当观测数据是低维度的手工测量时，检测交互作用只需进行简单的统计检验，但如何检测影响潜在变量的扰动之间的交互作用并不明显。我们推导出了两种基于成对干预的交互检验，并展示了如何将这些检验集成到主动学习管道中，以高效地发现扰动之间成对的交互作用。我们以生物学为背景说明了这些测试的价值，在生物学中，成对扰动实验经常被用来揭示无法从任何单一扰动中观察到的相互作用。我们的测试可以在非结构化数据（如图像中的像素）上运行，这使得交互作用的概念比典型的细胞活力实验更为宽泛，而且可以在成本更低的实验测定上运行。我们在几个合成和真实生物实验中验证了我们的测试能够有效识别相互作用对。我们在一个真实的生物实验中评估了我们的方法，在该实验中我们敲除了 50 对基因，并通过显微镜图像测量了效果。结果表明，与随机搜索和标准主动学习基线相比，我们能够恢复更多的已知生物相互作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - STAT - Machine Learning

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