Recent Developments in Sediment Toxicity Testing

IF 3.6 4区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES Environmental Toxicology and Chemistry Pub Date : 2024-06-24 DOI:10.1002/etc.5942
Michiel T. O. Jonker, Alan J. Jones
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Sediment toxicity tests have been developed to investigate potential toxicity to benthic species; these assays typically test the survival (or other response) of organisms after exposure to sediments collected from the field or contaminated in the laboratory. The array of sediment toxicity tests originally developed has gone through several iterations, resulting in the current use of standardized assays that employ standard test organisms and simple, easily quantifiable responses (e.g., death or reproduction). However, the field of sediment toxicity testing continues to evolve through new assays, test organisms, and dosing strategies.</p><p>In early 2022, a (virtual) workshop was organized as part of a European Chemical Industry Council–funded project (Cefic-LRI ECO43). Although the ECO43 project specifically focused on improving sediment toxicity testing with difficult-to-test, highly hydrophobic organic substances, the scope of the workshop reached beyond this focus. Approximately 40 people from academia, industry, and the regulatory field discussed the current status and future challenges and needs of sediment toxicity testing for plant protection products, substances of unknown or variable composition, complex reaction products and biological materials (UVCBs), offshore chemicals, and field sediments, as well as modeling and regulatory aspects of sediment toxicity. After the workshop, the idea arose to write critical reviews on the topics discussed during the workshop, combine these with manuscripts resulting from the Cefic-LRI ECO43 project, stimulate colleagues to write other manuscripts on sediment toxicity testing, and publish the collection of manuscripts in a special series in <i>Environmental Toxicology and Chemistry</i>. To identify colleagues who would be interested in jointly submitting manuscripts on sediment toxicity testing, forces were joined with the Society of Environmental Toxicology and Chemistry Sediment Interest Group, which has been active in the field of sediment research for many years, with sediment toxicity being one of its core topics. Despite the busy schedule of all our sediment toxicity colleagues, we managed to put together a collection of eight interesting scientific papers, all dealing with sediment toxicity testing, and particularly focusing on recent developments in this important field of environmental research.</p><p>In the first paper, Leppanen et al. (<span>2024</span>) provide an overview of where (in which countries), why (with what purpose), and how sediment toxicity tests should be performed. Moreover, in their critical review, they list several current needs and challenges and identify possible improvements in terms of regulations and actual testing. One of the challenges identified by the authors is the use of standard tests for difficult-to-test chemicals, such as nanomaterials, very hydrophobic substances and UVCBs. Generally, sediment toxicity tests have been developed using easy-to-test chemicals. By straightforwardly applying the tests to chemicals with potentially more complex behavior and not acknowledging that these chemicals may require alternative ways of handling or data interpretation, biased data could result. Along this line of reasoning, Jonker and Diepens (<span>2024a</span>) critically evaluate the performance of standard sediment toxicity assays for very hydrophobic organic chemicals (VHOCs) and show that although the assays perform well in terms of certain specific aspects, they do not perform well in others. In particular, the methods of spiking (i.e., the means of introducing the test chemicals into the sediment phase) and equilibrating appear to be crucial for these chemicals. 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引用次数: 0

Abstract

Sediment is an important environmental compartment inhabited by many different aquatic species, including benthic plants, vertebrates, and invertebrates. These species rely on the sediment for rooting, shelter, and/or feeding. Unfortunately, sediments also act as an important sink of certain anthropogenic contaminants, such as heavy metals and hydrophobic organic chemicals, which tend to accumulate in this aquatic compartment. Because many of these contaminants are toxic, they can potentially impact natural processes or habitat quality and thereby be harmful to aquatic ecosystems. Sediment toxicity tests have been developed to investigate potential toxicity to benthic species; these assays typically test the survival (or other response) of organisms after exposure to sediments collected from the field or contaminated in the laboratory. The array of sediment toxicity tests originally developed has gone through several iterations, resulting in the current use of standardized assays that employ standard test organisms and simple, easily quantifiable responses (e.g., death or reproduction). However, the field of sediment toxicity testing continues to evolve through new assays, test organisms, and dosing strategies.

In early 2022, a (virtual) workshop was organized as part of a European Chemical Industry Council–funded project (Cefic-LRI ECO43). Although the ECO43 project specifically focused on improving sediment toxicity testing with difficult-to-test, highly hydrophobic organic substances, the scope of the workshop reached beyond this focus. Approximately 40 people from academia, industry, and the regulatory field discussed the current status and future challenges and needs of sediment toxicity testing for plant protection products, substances of unknown or variable composition, complex reaction products and biological materials (UVCBs), offshore chemicals, and field sediments, as well as modeling and regulatory aspects of sediment toxicity. After the workshop, the idea arose to write critical reviews on the topics discussed during the workshop, combine these with manuscripts resulting from the Cefic-LRI ECO43 project, stimulate colleagues to write other manuscripts on sediment toxicity testing, and publish the collection of manuscripts in a special series in Environmental Toxicology and Chemistry. To identify colleagues who would be interested in jointly submitting manuscripts on sediment toxicity testing, forces were joined with the Society of Environmental Toxicology and Chemistry Sediment Interest Group, which has been active in the field of sediment research for many years, with sediment toxicity being one of its core topics. Despite the busy schedule of all our sediment toxicity colleagues, we managed to put together a collection of eight interesting scientific papers, all dealing with sediment toxicity testing, and particularly focusing on recent developments in this important field of environmental research.

In the first paper, Leppanen et al. (2024) provide an overview of where (in which countries), why (with what purpose), and how sediment toxicity tests should be performed. Moreover, in their critical review, they list several current needs and challenges and identify possible improvements in terms of regulations and actual testing. One of the challenges identified by the authors is the use of standard tests for difficult-to-test chemicals, such as nanomaterials, very hydrophobic substances and UVCBs. Generally, sediment toxicity tests have been developed using easy-to-test chemicals. By straightforwardly applying the tests to chemicals with potentially more complex behavior and not acknowledging that these chemicals may require alternative ways of handling or data interpretation, biased data could result. Along this line of reasoning, Jonker and Diepens (2024a) critically evaluate the performance of standard sediment toxicity assays for very hydrophobic organic chemicals (VHOCs) and show that although the assays perform well in terms of certain specific aspects, they do not perform well in others. In particular, the methods of spiking (i.e., the means of introducing the test chemicals into the sediment phase) and equilibrating appear to be crucial for these chemicals. In a second study from these authors, additional challenges when working with liquid VHOCs are illustrated, but that study also shows that potential artifacts (notably false-positive responses caused by fouling of test organisms with liquid substances) can be circumvented by applying a well-thought-out test design, provided that spiking is performed appropriately (Jonker & Diepens, 2024b).

Spiking is also the subject of two other studies (Valenti et al., 2023; Fischer et al., 2022). Although Jonker and Diepens (2024a) demonstrate that spiking sediments according to an alternative approach based on passive dosing is not successful for liquid substances, Fischer et al. (2022) show that the use of this technique can actually produce stable concentrations of solid chemicals in porewater of sediments. Moreover, by using this approach and subsequently performing additional measurements, the role of dissolved organic carbon in sediment toxicity testing is illustrated. Valenti et al. (2023), on the other hand, focus on the traditional spiking method, that is, with the use of a spiking solvent. Generally, solvents are being used to be able to dose sediments with poorly soluble compounds. This approach calls for additional control systems, to evaluate any effects of residual solvent. Valenti et al. (2023) demonstrate that residual solvent is rare and when properly controlled, the use of both a solvent and a negative control can be eliminated, thereby reducing the use of test organisms and systems without jeopardizing test quality.

An important choice to make when one is designing a sediment toxicity test is whether to use artificial or natural sediment. As also mentioned by Leppanen et al. (2024), the use of natural sediment could make a test more ecologically relevant. This consideration prompted Grønlund et al. (2023) to critically evaluate the pros and cons of applying natural field-collected sediments and to formulate a list of criteria to fulfill when using such sediments in actual toxicity testing. Subsequently, Grønlund et al. (2024) used actual field-collected sediments to perform sediment toxicity tests with the aim of answering the (mechanistic) questions of whether mixture toxicity occurs when multiple contaminants are tested simultaneously and whether any observed toxicity can be described and predicted with models. The last question seamlessly links to one of the recommendations by Leppanen et al. (2024), that is, to explore the potential use of models in sediment toxicity testing in more detail. For this reason and because models are not being used to their fullest potential, Burgess et al. (2023) finally provide a critical review of the different types of models that can be used for this purpose. They conclude with a statement of critical needs, with the aim of broadening the application of mechanistic models in sediment toxicity testing.

All in all, the present collection of studies covers several important steps and aspects at play within the field of sediment toxicity testing, from regulatory aspects to detailed experimental and toxicological issues and modeling. We hope that regulators, academics, people from industry, and consultants will be informed and inspired to improve the current testing by implementing new developments and continuing to improve sediment toxicity testing in the future.

The authors declare no conflicts of interest.

Michiel T. O. Jonker: Writing—original draft. Alan J. Jones: Writing—review & editing.

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沉积物毒性测试的最新发展。
沉积物是许多不同水生物种(包括底栖植物、脊椎动物和无脊椎动物)栖息的重要环境区划。这些物种依靠沉积物生根、栖息和/或觅食。不幸的是,沉积物也是某些人为污染物(如重金属和疏水性有机化学物质)的重要汇集地,这些污染物往往会在这一水生区块中积累。由于其中许多污染物具有毒性,它们可能会影响自然过程或栖息地质量,从而对水生生态系统造成危害。沉积物毒性测试是为了研究底栖物种的潜在毒性而开发的;这些测试通常是测试生物在暴露于从野外收集或在实验室中受到污染的沉积物后的存活率(或其他反应)。最初开发的一系列沉积物毒性测试方法经过多次迭代,最终形成了目前使用的标准化测试方法,这些方法采用标准测试生物和简单、易于量化的反应(如死亡或繁殖)。然而,沉积物毒性测试领域仍在通过新的测定方法、测试生物和剂量策略不断发展。2022 年初,作为欧洲化学工业理事会资助项目(Cefic-LRI ECO43)的一部分,组织了一次(虚拟)研讨会。尽管 ECO43 项目特别关注改进沉积物毒性测试,使用难以测试的高疏水性有机物质,但研讨会的范围超出了这一重点。来自学术界、工业界和监管领域的约 40 人讨论了植物保护产品、未知或可变成分物质、复杂反应产物和生物材料 (UVCB)、近海化学品和野外沉积物的沉积物毒性测试的现状、未来挑战和需求,以及沉积物毒性的建模和监管问题。研讨会结束后,我们萌生了一个想法:就研讨会上讨论的主题撰写评论文章,将这些文章与 Cefic-LRI ECO43 项目的手稿结合起来,激励同事们撰写有关沉积物毒性测试的其他手稿,并在《环境毒理学与化学》杂志上以特别系列的形式出版手稿集。为了找到有兴趣共同提交沉积物毒性测试手稿的同行,我们与环境毒理学和化学学会沉积物兴趣小组进行了合作,该兴趣小组多年来一直活跃在沉积物研究领域,沉积物毒性是其核心主题之一。尽管沉积物毒性研究领域的所有同行都工作繁忙,但我们还是设法收集了八篇有趣的科学论文,全部涉及沉积物毒性测试,尤其关注这一重要环境研究领域的最新进展。在第一篇论文中,Leppanen 等人(2024 年)概述了在哪里(哪些国家)、为什么(目的是什么)以及如何进行沉积物毒性测试。此外,他们在批判性评论中列出了当前的一些需求和挑战,并指出了在法规和实际测试方面可能的改进。作者指出的挑战之一是如何对难以测试的化学品(如纳米材料、疏水性极强的物质和超低氯苯)进行标准测试。一般来说,沉积物毒性测试是使用易于测试的化学品开发的。将测试直接应用于行为可能更复杂的化学品,而不考虑这些化学品可能需要其他处理方法或数据解释,可能会导致数据偏差。根据这一思路,Jonker 和 Diepens(2024a)对标准沉积物毒性检测方法在疏水性有机化学品 (VHOC) 方面的性能进行了严格评估,结果表明,尽管这些检测方法在某些特定方面表现良好,但在其他方面却不尽如人意。特别是,对于这些化学品来说,添加方法(即将测试化学品引入沉积物相中的方法)和平衡方法似乎至关重要。在这些作者的第二项研究中,说明了在使用液态 VHOCs 时所面临的额外挑战,但该研究也表明,只要加标操作得当,通过采用深思熟虑的测试设计,就可以规避潜在的假象(特别是测试生物体与液态物质结垢所导致的假阳性反应)(Jonker &amp; Diepens,2024b)。尽管 Jonker 和 Diepens(2024a)证明,根据基于被动加药的替代方法对沉积物进行加标对液态物质来说并不成功,但 Fischer 等(2022b)却证明了这一点。
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来源期刊
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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Correction. Spotlights are papers selected by editors published in peer-reviewed journals that may be more regionally specific or appearing in languages other than English Issue Information - Cover Editorial Board and Table of Contents Detection and Prediction of Toxic Aluminum Concentrations in High-Priority Salmon Rivers in Nova Scotia.
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