1. Developing predictive models for toxicity of organic chemicals to green algae based on mode of action
- Author
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Jianrong Chen, Hongjun Lin, Xiaoxuan Wei, Xinya Yang, Serge Bakire, Haiying Yu, and Guangcai Ma
- Subjects
Quantitative structure–activity relationship ,Environmental Engineering ,Health, Toxicology and Mutagenesis ,Quantitative Structure-Activity Relationship ,Modes of toxic action ,010501 environmental sciences ,Biology ,01 natural sciences ,chemistry.chemical_compound ,Chlorophyta ,Molecular descriptor ,Environmental Chemistry ,Animals ,Computer Simulation ,Organic Chemicals ,Mode of action ,Ecosystem ,0105 earth and related environmental sciences ,Molecular Structure ,Aquatic ecosystem ,Public Health, Environmental and Occupational Health ,Environmental engineering ,General Medicine ,General Chemistry ,Models, Theoretical ,biology.organism_classification ,Pollution ,0104 chemical sciences ,010404 medicinal & biomolecular chemistry ,chemistry ,Toxicity ,Green algae ,Biochemical engineering ,Growth inhibition - Abstract
Organic chemicals in the aquatic ecosystem may inhibit algae growth and subsequently lead to the decline of primary productivity. Growth inhibition tests are required for ecotoxicological assessments for regulatory purposes. In silico study is playing an important role in replacing or reducing animal tests and decreasing experimental expense due to its efficiency. In this work, a series of theoretical models was developed for predicting algal growth inhibition (log EC 50 ) after 72 h exposure to diverse chemicals. In total 348 organic compounds were classified into five modes of toxic action using the Verhaar Scheme. Each model was established by using molecular descriptors that characterize electronic and structural properties. The external validation and leave-one-out cross validation proved the statistical robustness of the derived models. Thus they can be used to predict log EC 50 values of chemicals that lack authorized algal growth inhibition values (72 h). This work systematically studied algal growth inhibition according to toxic modes and the developed model suite covers all five toxic modes. The outcome of this research will promote toxic mechanism analysis and be made applicable to structural diversity.
- Published
- 2017