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Toxicity bioassays for water from black-odor rivers in Wenzhou, China

  • Developments and Applications of Environmental Specimen Banks for Monitoring Emerging Contaminants
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Abstract

Following urbanization, a large number of urban rivers were contaminated and turned to black-odor rivers. The traditional approach for detecting water quality is based on chemical or physical analysis. However, biological toxicity of black-odor water has been less addressed. As two typical black-odor rivers, Jiushanwai River (JS) and Shanxia River (SX) are tributaries of Wen-Rui Tang River in Wenzhou (south of China). The eco-safety of the urban rivers was evaluated by bioassay for water toxicity in this study. Ten and 5 sampling sites were respectively set along JS and SX. Water samples were collected monthly from October 2010 to October 2011. The general physical and chemical parameters of river water were monitored. In order to investigate the ecotoxicological effects of black-odor water, the following bioassays were used: (1) Fish acute toxicity test (Danio rerio, comprehensive toxicity), (2) luminescent bacteria bioassay (Qinghaiensis vibrio, toxicity to bacteria), and (3) tropical claw embryo assay (Xenopus tropicalis, embryo toxicity). Biotoxicity of black-odor rivers water was demonstrated by D. rerio, Q. vibrio, and X. tropicalis embryos. Toxicological effects of black-odor water were respectively shown by mortality of zebrafish, and by the relative inhibitory light rate of luminescent bacteria. However, luminescent bacteria were more sensitive to inspect biotoxicity than zebrafish. In X. tropicalis embryos test, toxicological effects of black-odor water were mostly shown by embryos’ survival rate and teratogenic rate. Bioassay results showed that toxicity of SX water was higher than that of JS water, especially in summer. Statistical analysis of luminescent bacteria toxicity test showed that biotoxicity of SX and JS was high in summer, but low in winter and spring. The seasonal changes of water toxicity of the black-odor river were positively correlative with changes of water temperature (p < 0.05), and related to pH and ammonium nitrogen of water. Typical black-odor river water displays different degrees of biotoxicity to D. rerio, luminescent bacteria, and X. tropicalis embryos. The ecotoxicological risk of black-odor rivers was demonstrated in urban area, which suggests bioassay is necessary for evaluation of water quality. In the present study, spatial and seasonal bioassay for toxicity of JS and SX provides a complete example for evaluation of urban rivers.

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Acknowledgments

This study was supported by National Science and Technology Major Project of China (no. 2009ZX07317-006), a grant from the Natural Science Foundation of Shanghai (11ZR1410500), and a grant from Shanghai Institute of Urban Ecology and Sustainability (no. SHUES2011A02).

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Authors and Affiliations

  1. Department of Environmental Science and Technology, East China Normal University, 500# DongChuan RD, Shanghai, China, 200241

    He DeFu, Chen RuiRui, Zhu EnHui, Chen Na, Yang Bo & Huang MinSheng

  2. Shanghai Key Lab for Urban Ecological Processes and Eco-Restoration, Shanghai, China, 200241

    He DeFu & Huang MinSheng

  3. State Key Laboratory of Estuarine and Coastal Research, Shanghai, China, 200062

    Yang Bo & Shi HuaHong

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  1. He DeFu
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  2. Chen RuiRui
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  4. Chen Na
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  6. Shi HuaHong
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  7. Huang MinSheng
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Correspondence to He DeFu.

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Responsible editor: Henner Hollert

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DeFu, H., RuiRui, C., EnHui, Z. et al. Toxicity bioassays for water from black-odor rivers in Wenzhou, China. Environ Sci Pollut Res 22, 1731–1741 (2015). https://doi.org/10.1007/s11356-013-2484-1

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