Affiliation:
1. Finnish Environment Institute Jyväskylä Finland
2. Toxicology Department, TotalEnergies Paris La Défense France
3. Atlantic Coastal Environmental Science Division, Office of Research and Development US Environmental Protection Agency Narragansett Rhode Island
4. CSIRO Environment Brisbane Queensland Australia
5. School of Environmental Sciences, Ontario Agricultural College University of Guelph Guelph Ontario Canada
6. Institute for Risk Assessment Sciences Utrecht University Utrecht The Netherlands
Abstract
AbstractSediments are an integral component of aquatic systems, linking multiple water uses, functions, and services. Contamination of sediments by chemicals is a worldwide problem, with many jurisdictions trying to prevent future pollution (prospective) and manage existing contamination (retrospective). The present review assesses the implementation of sediment toxicity testing in environmental regulations globally. Currently, the incorporation of sediment toxicity testing in regulations is most common in the European Union (EU), North America, and Australasian regions, with some expansion in Asia and non‐EU Europe. Employing sediment toxicity testing in prospective assessments (i.e., before chemicals are allowed on the market) is most advanced and harmonized with pesticides. In the retrospective assessment of environmental risks (i.e., chemicals already contaminating sediments), regulatory sediment toxicity testing practices are applied inconsistently on the global scale. International harmonization of sediment toxicity tests is considered an asset and has been successful through the widespread adoption and deployment of Organisation for Economic Co‐operation and Development guidelines. On the other hand, retrospective sediment assessments benefit from incorporating regional species and protocols. Currently used toxicity testing species are diverse, with temperate species being applied most often, whereas test protocols are insufficiently flexible to appropriately address the range of environmental contaminants, including nanomaterials, highly hydrophobic contaminants, and ionized chemicals. The ever‐increasing and ‐changing pressures placed on aquatic resources are a challenge for protection and management efforts, calling for continuous sediment toxicity test method improvement to insure effective use in regulatory frameworks. Future developments should focus on including more subtle and specific toxicity endpoints (e.g., incorporating bioavailability‐based in vitro tests) and genomic techniques, extending sediment toxicity testing from single to multispecies approaches, and providing a better link with ecological protection goals. Environ Toxicol Chem 2024;43:1697–1716. © 2024 The Authors. Environmental Toxicology and Chemistry published by Wiley Periodicals LLC on behalf of SETAC.
Reference172 articles.
1. Impacts of suspended sediment and metal pollution from mining activities on riverine fish population—a review
2. Assessing and Managing Contaminated Sediments: Part I, Developing an Effective Investigation and Risk Evaluation Strategy
3. ASTM International. (2020).Standard test method for measuring the toxicity of sediment‐associated contaminants with freshwater invertebrates(E1706 – 20).
4. ASTM International. (2023).Standards & publications.http://www.astm.org/Standard/standards-and-publications.html
5. Australian and New Zealand Governments and Australian State and Territory Governments. (2018a). National water quality management strategy.https://www.waterquality.gov.au/sites/default/files/documents/nwqms-charter_0.pdf
Cited by
2 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献