Characterizing Freshwater Ecotoxicity of More Than 9000 Chemicals by Combining Different Levels of Available Measured Test Data with In Silico Predictions

IF 3.6 4区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES Environmental Toxicology and Chemistry Pub Date : 2024-06-11 DOI:10.1002/etc.5929

Mélanie Douziech, Susan Anyango Oginah, Laura Golsteijn, Michael Zwicky Hauschild, Olivier Jolliet, Mikołaj Owsianiak, Leo Posthuma, Peter Fantke

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Abstract

Ecotoxicological impacts of chemicals released into the environment are characterized by combining fate, exposure, and effects. For characterizing effects, species sensitivity distributions (SSDs) estimate toxic pressures of chemicals as the potentially affected fraction of species. Life cycle assessment (LCA) uses SSDs to identify products with lowest ecotoxicological impacts. To reflect ambient concentrations, the Global Life Cycle Impact Assessment Method (GLAM) ecotoxicity task force recently recommended deriving SSDs for LCA based on chronic EC10s (10% effect concentration, for a life-history trait) and using the 20th percentile of an EC10-based SSD as a working point. However, because we lacked measured effect concentrations, impacts of only few chemicals were assessed, underlining data limitations for decision support. The aims of this paper were therefore to derive and validate freshwater SSDs by combining measured effect concentrations with in silico methods. Freshwater effect factors (EFs) and uncertainty estimates for use in GLAM-consistent life cycle impact assessment were then derived by combining three elements: (1) using intraspecies extrapolating effect data to estimate EC10s, (2) using interspecies quantitative structure–activity relationships, or (3) assuming a constant slope of 0.7 to derive SSDs. Species sensitivity distributions, associated EFs, and EF confidence intervals for 9862 chemicals, including data-poor ones, were estimated based on these elements. Intraspecies extrapolations and the fixed slope approach were most often applied. The resulting EFs were consistent with EFs derived from SSD-EC50 models, implying a similar chemical ecotoxicity rank order and method robustness. Our approach is an important step toward considering the potential ecotoxic impacts of chemicals currently neglected in assessment frameworks due to limited test data. Environ Toxicol Chem 2024;43:1914–1927. © 2024 The Author(s). Environmental Toxicology and Chemistry published by Wiley Periodicals LLC on behalf of SETAC.

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通过将不同水平的可用测量测试数据与硅学预测相结合，确定 9000 多种化学品的淡水生态毒性特征。

释放到环境中的化学品的生态毒理学影响是通过结合归宿、暴露和效应来描述的。为描述影响，物种敏感性分布（SSD）将化学品的毒性压力估算为可能受影响物种的比例。生命周期评估（LCA）使用物种敏感性分布来确定对生态毒理学影响最小的产品。为了反映环境浓度，全球生命周期影响评估方法（GLAM）生态毒性工作组最近建议，根据慢性 EC10（对于生命史特征而言，10% 的影响浓度）推导出生命周期影响评估的 SSD，并将基于 EC10 的 SSD 的 20 百分位数作为工作点。然而，由于我们缺乏测量的效应浓度，因此只评估了少数化学品的影响，这凸显了决策支持数据的局限性。因此，本文旨在通过将测量的效应浓度与硅学方法相结合，得出并验证淡水 SSD。然后，结合以下三个要素，得出淡水影响因子（EF）和不确定性估计值，用于与 GLAM 一致的生命周期影响评估：(1)使用种内效应外推数据估算 EC10，(2)使用种间定量结构-活性关系，或(3)假设 0.7 的恒定斜率得出 SSD。根据这些要素估算了 9862 种化学品（包括数据贫乏的化学品）的物种敏感性分布、相关 EF 和 EF 置信区间。物种内推断法和固定斜率法是最常用的方法。得出的 EF 与 SSD-EC50 模型得出的 EF 一致，这意味着化学生态毒性等级顺序和方法的稳健性相似。我们的方法是考虑化学品潜在生态毒性影响的重要一步，目前由于测试数据有限，这些影响在评估框架中被忽视了。环境毒物化学 2024;00:1-14。© 2024 作者。环境毒理学与化学》由 Wiley Periodicals LLC 代表 SETAC 出版。

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来源期刊

Environmental Toxicology and Chemistry 环境科学-毒理学

CiteScore

7.40

自引率

9.80%

发文量

265

审稿时长

3.4 months

期刊介绍： The Society of Environmental Toxicology and Chemistry (SETAC) publishes two journals: Environmental Toxicology and Chemistry (ET&C) and Integrated Environmental Assessment and Management (IEAM). Environmental Toxicology and Chemistry is dedicated to furthering scientific knowledge and disseminating information on environmental toxicology and chemistry, including the application of these sciences to risk assessment.[...] Environmental Toxicology and Chemistry is interdisciplinary in scope and integrates the fields of environmental toxicology; environmental, analytical, and molecular chemistry; ecology; physiology; biochemistry; microbiology; genetics; genomics; environmental engineering; chemical, environmental, and biological modeling; epidemiology; and earth sciences. ET&C seeks to publish papers describing original experimental or theoretical work that significantly advances understanding in the area of environmental toxicology, environmental chemistry and hazard/risk assessment. Emphasis is given to papers that enhance capabilities for the prediction, measurement, and assessment of the fate and effects of chemicals in the environment, rather than simply providing additional data. The scientific impact of papers is judged in terms of the breadth and depth of the findings and the expected influence on existing or future scientific practice. Methodological papers must make clear not only how the work differs from existing practice, but the significance of these differences to the field. Site-based research or monitoring must have regional or global implications beyond the particular site, such as evaluating processes, mechanisms, or theory under a natural environmental setting.