Improving Sediment Toxicity Testing for Very Hydrophobic Chemicals: Part 2—Exposure Duration, Upper Limit Test Concentrations, and Distinguishing Actual Toxicity from Physical Effects

IF 3.6 4区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Environmental Toxicology and Chemistry Pub Date : 2024-02-08 DOI:10.1002/etc.5801

Michiel T. O. Jonker, Noël J. Diepens

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Abstract

Sediment toxicity testing with very hydrophobic organic chemicals (VHOCs) is challenging because of the chemicals’ low aqueous solubilities and slow kinetics. The present study presents the results of experiments investigating whether the standard exposure duration of 28 days with benthic invertebrates is sufficient for VHOCs; above which concentrations in sediment VHOCs are present as “free phase,” that is, crystals or non-aqueous-phase liquids (NAPLs); and whether it is possible to discriminate between actual VHOC toxicity and physical effects caused by NAPLs through fouling of the test organisms. The results suggest that the standard sediment toxicity test duration is sufficient for obtaining steady-state VHOC concentrations in Hyalella azteca and Lumbriculus variegatus, provided that spiking and equilibration are performed properly (i.e., no free phase present). Under these conditions, transient (days 3–20) peak-shaped toxicokinetics were observed, with steady-state concentrations reached at approximately 28 days. The concentration above which NAPLs are present, the so-called critical separate phase concentration (CSPC), was determined for several VHOCs by modeling and two experimental methods. Modeling resulted in unrealistic and variable data and therefore should be applied with caution. Experimentally determining CSPCs was successful and yielded values of approximately 1000 (400–2000) mg/kg dry weight, depending on the chemical. Finally, it was demonstrated that distinguishing actual toxicity from physical effects is possible by applying a well-considered test setup, combining toxicity tests with multiple invertebrates (including Lumbriculus, which serves as a negative control for fouling); a broad test concentration range, preferably up to at least 30 000 mg/kg; and passive sampling to localize the CSPC. Applying this setup, false-positive effects due to fouling, as well as false-negative results due to testing at too low concentrations (trying to stay below the CSPC), can be avoided. Environ Toxicol Chem 2024;43:1728–1739. © 2023 The Authors. Environmental Toxicology and Chemistry published by Wiley Periodicals LLC on behalf of SETAC.

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改进疏水性极强化学品的沉积物毒性测试：第 2 部分--暴露时间、上限测试浓度以及区分实际毒性和物理效应。

疏水性有机化学品（VHOCs）的沉积物毒性测试具有挑战性，因为这些化学物质的水溶解度低、动力学速度慢。本研究介绍了以下实验的结果：底栖无脊椎动物 28 天的标准接触时间是否足以检测 VHOC；VHOC 在沉积物中的浓度超过多少时会以 "游离相"（即晶体或非水相液体 (NAPL)）的形式存在；以及是否有可能区分 VHOC 的实际毒性和 NAPL 通过弄脏测试生物而造成的物理影响。结果表明，标准沉积物毒性试验持续时间足以在 Hyalella azteca 和 Lumbriculus variegatus 中获得稳态 VHOC 浓度，前提是正确执行加标和平衡（即不存在游离相）。在这些条件下，可观察到瞬时（第 3-20 天）峰值型毒物动力学，约 28 天后达到稳态浓度。通过建模和两种实验方法，确定了几种 VHOCs 的 NAPLs 浓度，即所谓的临界分离相浓度 (CSPC)。建模得出的数据不真实，且变化较大，因此应谨慎应用。通过实验确定 CSPC 是成功的，得出的数值约为 1000（400-2000）毫克/千克干重，具体数值取决于化学品。最后，实验证明，通过以下方法可以将实际毒性与物理效应区分开来：采用经过深思熟虑的试验装置，结合多种无脊椎动物（包括作为污垢阴性对照的 Lumbriculus）进行毒性试验；试验浓度范围较宽，最好至少达到 30 000 mg/kg；以及被动取样以定位 CSPC。采用这种设置，可以避免由于污垢造成的假阳性效应，以及由于测试浓度过低（试图保持在 CSPC 以下）造成的假阴性结果。环境毒物化学 2024;00:1-12。© 2023 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.

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