Machine learning to predict developmental neurotoxicity with high-throughput data from 2D bio-engineered tissues.

Finn Kuusisto, Vitor Santos Costa, Zhonggang Hou, James Thomson, David Page, Ron Stewart
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引用次数: 4

Abstract

There is a growing need for fast and accurate methods for testing developmental neurotoxicity across several chemical exposure sources. Current approaches, such as in vivo animal studies, and assays of animal and human primary cell cultures, suffer from challenges related to time, cost, and applicability to human physiology. Prior work has demonstrated success employing machine learning to predict developmental neurotoxicity using gene expression data collected from human 3D tissue models exposed to various compounds. The 3D model is biologically similar to developing neural structures, but its complexity necessitates extensive expertise and effort to employ. By instead focusing solely on constructing an assay of developmental neurotoxicity, we propose that a simpler 2D tissue model may prove sufficient. We thus compare the accuracy of predictive models trained on data from a 2D tissue model with those trained on data from a 3D tissue model, and find the 2D model to be substantially more accurate. Furthermore, we find the 2D model to be more robust under stringent gene set selection, whereas the 3D model suffers substantial accuracy degradation. While both approaches have advantages and disadvantages, we propose that our described 2D approach could be a valuable tool for decision makers when prioritizing neurotoxicity screening.

利用2D生物工程组织的高通量数据预测发育神经毒性的机器学习。
越来越需要快速和准确的方法来测试几种化学暴露源的发育神经毒性。目前的方法,如动物体内研究,以及动物和人类原代细胞培养的测定,受到时间、成本和对人类生理学适用性的挑战。先前的工作已经证明,利用机器学习来预测发育性神经毒性是成功的,使用的是暴露于各种化合物的人体3D组织模型收集的基因表达数据。3D模型在生物学上类似于开发神经结构,但其复杂性需要广泛的专业知识和努力。而不是专注于构建发育神经毒性的分析,我们提出一个更简单的二维组织模型可能证明是足够的。因此,我们比较了基于二维组织模型和基于三维组织模型的预测模型的准确性,发现二维模型的准确性要高得多。此外,我们发现2D模型在严格的基因集选择下更具鲁棒性,而3D模型则遭受严重的精度下降。虽然这两种方法都有优点和缺点,但我们认为,我们所描述的2D方法可能是决策者在优先考虑神经毒性筛查时的有价值的工具。
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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