Machine Learning-Driven Cross-Species Toxicity Prediction for Advancing Ecologically Relevant PFAS Water Quality Criteria

Machine Learning-Driven Cross-Species Toxicity Prediction for Advancing Ecologically Relevant PFAS Water Quality Criteria

Traditional toxicity testing cannot keep pace with the rapid growth of synthetic chemicals, creating major data gaps that hinder the development of water quality criteria (WQC) for emerging contaminants. This study developed a machine learning model integrating compound- and organism-related feature...

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Wedi'i Gadw mewn:
Manylion Llyfryddiaeth
Prif Awdur: Weigang Liang (734333) (author)
Awduron Eraill: Jingya Li (309241) (author), Xiaolei Wang (139592) (author), John P. Giesy (302766) (author), Xiaoli Zhao (118708) (author)
Cyhoeddwyd: 2025
Pynciau:
Ecology
Inorganic Chemistry
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
potentially reflecting inter
30 representative per
water quality criteria
informed species selection
5 </ sub
species toxicity prediction
species prediction
species sensitivity
existing criteria
acute toxicity
synthetic chemicals
study developed
related features
regional differences
regional comparisons
rapid growth
polyfluoroalkyl substances
perfluorooctanoic acid
perfluorooctanesulfonic acid
north america
model predicted
machine learning
hazardous concentrations
emerging contaminants
dominant predictors
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Crynodeb:Traditional toxicity testing cannot keep pace with the rapid growth of synthetic chemicals, creating major data gaps that hinder the development of water quality criteria (WQC) for emerging contaminants. This study developed a machine learning model integrating compound- and organism-related features to enable cross-compound and cross-species toxicity prediction. The model demonstrated strong robustness and generalization, outperforming the Interspecies Correlation Estimation application in cross-species prediction, particularly across large taxonomic distances. SHAP analysis identified water solubility and lipophilicity as dominant predictors, with organism-related features also contributing substantially. The model predicted the acute toxicity of 30 representative per- and polyfluoroalkyl substances (PFAS) across 181 aquatic species. Habitat-informed species selection was then used to derive ecologically relevant 5% hazardous concentrations (HC<sub>5</sub>), which were generally higher in saltwater than in freshwater. Cross-regional comparisons further indicated that salinity may modulate fish sensitivity to PFAS. HC<sub>5</sub> estimates for China were higher than those for North America and Europe, potentially reflecting inter-regional differences in species sensitivity, with Chinese species appearing comparatively more tolerant. Finally, site-specific WQC for perfluorooctanoic acid (PFOA) and perfluorooctanesulfonic acid (PFOS) were derived for the Great Lakes using predicted sensitivities of 76 dominant native species, providing greater ecological relevance than existing criteria.

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