生物转化
数量结构-活动关系
代谢途径
人工神经网络
转化(遗传学)
毒性
计算生物学
图形
计算机科学
生化工程
急性毒性
化学
计算
人工智能
生物系统
小桶
机器学习
危害
毒物
反向传播
深层神经网络
序列(生物学)
危害分析
计算模型
作者
Supaporn Klabklaydee,Bei Zhang,Jibao Liu,Nopphakorn Subsa-Ard,Mohamed Elsamadony,Manabu Fujii
出处
期刊:ACS ES&T water
[American Chemical Society]
日期:2026-01-27
卷期号:6 (2): 697-708
标识
DOI:10.1021/acsestwater.5c00828
摘要
Predicting how chemical toxicity evolves during metabolism remains a central challenge in environmental toxicology. This study presents an integrated computational framework combining descriptor-based QSAR modeling, graph neural networks, and biotransformation pathway analysis to capture the dynamic nature of the chemical risk. An XGBoost model using PaDEL descriptors achieved high accuracy (R2 = 0.969), while a newly developed Graph Sequence Attention Network (GSAT) yielded comparable results (R2 = 0.907, mean absolute error (MAE) ≈ 0.30) with a 98.9% reduction in computation time, enabling high-throughput screening and substructure-level interpretation. Integrating GSAT with EnviPath-python and KEGG validation enabled the simulation of multigenerational toxicity for 12 priority pollutants. Across transformation networks, 68.2% of the transformation steps increased the toxicity, resulting in an average of a 15.4-fold increase. The most detoxifying pathways included polynuclear aromatic dioxygenation, decarboxylation to CO2, and the conversion of halogenated muconate to succinate, whereas alcohol oxidations consistently enhanced toxicity. Notably, 91.6% of the halogenated pathways showed net toxification, with 78.3% reaching peak levels during steps 3–4, indicating temporary periods of maximum hazard before detoxification. These findings reveal that metabolic transformations often increase toxicity and emphasize that pathway level rather than static toxicity assessment is essential for accurate environmental risk evaluation and the rational design of bioremediation strategies.
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