Strategies to include prior knowledge in omics analysis with deep neural networks.

IF 7.4 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Patterns Pub Date : 2025-03-14 DOI:10.1016/j.patter.2025.101203

Kisan Thapa, Meric Kinali, Shichao Pei, Augustin Luna, Özgün Babur

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Abstract

High-throughput molecular profiling technologies have revolutionized molecular biology research in the past decades. One important use of molecular data is to make predictions of phenotypes and other features of the organisms using machine learning algorithms. Deep learning models have become increasingly popular for this task due to their ability to learn complex non-linear patterns. Applying deep learning to molecular profiles, however, is challenging due to the very high dimensionality of the data and relatively small sample sizes, causing models to overfit. A solution is to incorporate biological prior knowledge to guide the learning algorithm for processing the functionally related input together. This helps regularize the models and improve their generalizability and interpretability. Here, we describe three major strategies proposed to use prior knowledge in deep learning models to make predictions based on molecular profiles. We review the related deep learning architectures, including the major ideas in relatively new graph neural networks.

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在深度神经网络组学分析中包含先验知识的策略。

过去几十年来，高通量分子剖析技术彻底改变了分子生物学研究。分子数据的一个重要用途是利用机器学习算法预测生物体的表型和其他特征。深度学习模型能够学习复杂的非线性模式，因此在这项任务中越来越受欢迎。然而，由于数据维度非常高，样本量相对较小，导致模型过拟合，因此将深度学习应用于分子图谱具有挑战性。一种解决方案是结合生物先验知识，指导学习算法一起处理功能相关的输入。这有助于对模型进行正则化处理，提高其通用性和可解释性。在此，我们介绍了在深度学习模型中使用先验知识根据分子特征进行预测的三种主要策略。我们回顾了相关的深度学习架构，包括相对较新的图神经网络的主要思想。

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