1.1 本指南描述了使用流通技术获取淡水和咸水鱼类以及咸水双壳类软体动物添加到稀释水中但不添加到食物中的试验材料的生物浓缩实验室数据的程序。这些程序对于其他水生物种的生物浓缩试验也很有用，尽管可能需要修改。 1.2 根据特殊需要或情况，可能需要对这些程序进行其他修改。虽然使用适当的程序比遵循规定的程序更重要，但使用不寻常程序进行的测试结果不太可能与许多其他测试的结果相比较。使用这些程序的修改版本和未修改版本获得的结果的比较可能提供有关进行生物浓缩试验的新概念和程序的有用信息。 1.3 这些程序适用于在水中和适当组织中以必要浓度准确测量的所有化学品。 生物浓缩试验通常在单个化学品上进行，但如果可以进行适当的测量，则可以在混合物上进行。本指南中描述的一些技术是为非电离有机化学品的测试开发的（见 11.1.2.1 )可能不适用于可电离或无机化学品。 1.4 生物浓缩试验的结果通常应根据表观稳态和预测稳态生物浓缩因子（BCF）以及吸收和净化速率常数进行报告。应根据鱼类的全身和双壳类软体动物的总软组织报告结果。对于人类食用的鱼类和扇贝，还应报告可食用部分的一些结果，特别是当人类摄入试验材料是一个主要问题时。对于有机和有机金属化学品的测试，应报告组织的脂质百分比。 1.5 本指南安排如下: 部分 参考文件 2. 术语 3. 指南摘要 4. 意义和用途 5. 安全注意事项 7. 仪器 6. 设施 6.1 建筑材料 6.2 计量系统 6.3 试验室 6.4 打扫 6.4.4 可接受性 6.5 稀释水 8. 要求 8.1 来源 8.2 治疗 8.3 刻画 8.4 试验材料 9 全体的 9.1 放射性标记材料 9.2 储备溶液 9.3 试验浓度 9.4 测试生物体 10 种 10.1 大小 10.2 来源 10.3 护理和处理 10.4 喂养 10.5 疾病治疗 10.6 霍尔丁 10.7 适应 10.8 质量 10.9 程序 11 实验设计 11.1 溶解氧 11.2 温度 11.3 加载 11.4 开始测试 11.5 生物体护理 11.6 喂养 11.7 打扫 11.8 生物学数据 11.9 测试溶液的测量 11.10 分析方法学 12 测试的可接受性 13 计算结果 14 文档 15 关键词 16 1.6 以国际单位制表示的数值应视为标准值。本标准不包括其他计量单位。 1.7 本标准并非旨在解决与其使用相关的所有安全问题（如有）。本标准的用户有责任在使用前制定适当的安全、健康和环境实践，并确定监管限制的适用性。 第节给出了具体的预防说明 7. . 本标准并非旨在解决与其使用相关的所有安全问题（如有）。本标准的用户有责任在使用前制定适当的安全和健康实践，并确定监管限制的适用性。 1.8 本国际标准是根据世界贸易组织技术性贸易壁垒（TBT）委员会发布的《关于制定国际标准、指南和建议的原则的决定》中确立的国际公认标准化原则制定的。 ====意义和用途====== 5.1 进行生物浓缩试验，以获取有关水生物种直接从水中积累试验材料的能力的信息。本指南为设计测试材料性能的生物浓缩测试提供了指导，以便以经济高效的方式测试每种材料。 5.2 由于稳态通常从低端接近，并且视稳态的定义基于统计假设检验，因此视稳态BCF通常低于稳态BCF。由于生物浓缩试验中常用的变化和样本量，实际稳态BCF通常不超过表观BCF的两倍。 5.3 当在同一测试中确定两者时，预测的稳态BCF通常高于表观稳态BCF，因为用于计算预测BCF的模型假设BCF在无限时间内稳定增加。 5.4 BCF以及吸收和净化的速率和程度将取决于温度、水质、物种及其大小、生理条件、年龄和其他因素 ( 1. ) . 4. 虽然在测试期间喂养了生物体，但在测试期间，通过吸附到食物上的方式进行的吸收可能可以忽略不计。 5.5 生物浓度测试的结果用于预测在类似条件下暴露在野外情况下水生生物中可能出现的浓度，但移动生物体可能避免暴露的情况除外。在实验条件下，与自然水系统相比，有意将颗粒物最小化。因此，对于具有高辛醇-水分配系数的有机化学品或基本上吸附在颗粒物上的无机化学品，测试的暴露条件可能无法进行比较。因此，在这两种情况下，溶液中受试物的量都会减少，因此许多生物体对该物质的利用率较低。 然而，吸附可能会增加摄入颗粒物的水生物种的生物累积 ( 2. ) 或者食物可能是鱼类中比水本身更重要的残留物来源，因为稳定的中性有机化学品具有对数 K 噢 在4到6之间 ( 3. ) . 5.6 生物浓缩试验的结果可用于比较不同材料的累积倾向。还可以使用稳态BCF与物理化学性质（如辛醇-水分配系数和水中溶解度）之间的相关性，对非电离有机化学品进行生物浓缩排名 ( 4. ). 然而，当此类预测不可能时，会超过已证明的相关性极限，或者可能存在其他问题 ( 1. , 5. ), 可能需要进行生物浓缩试验。 5.7 生物浓缩试验的结果也可用于比较不同物种积累材料的能力。 在稳态下，单个生物体和生物体内各种组织中非电离有机化学品的浓度可能与生物体和组织中脂质的浓度有关 ( 6. ). 5.8 在评估危险时，生物浓缩试验的结果可能是一个重要的考虑因素（见指南） E1023 )或者制定水质标准，因为食用动物可能会因摄入含有有毒物质的水生生物而受到不利影响。然而，对消费生物危害的评估不仅必须考虑水生生物组织中累积的物质数量，而且还必须考虑物质对消费者的毒性。此外，人类只吃大多数水生生物的某些部分，而其他食肉动物通常会消耗额外的组织。 5.9 生物浓缩试验可能有助于研究试验材料之间的结构-活性关系、生物可用性、水生生物中材料的代谢以及各种环境因素对此类试验结果的影响。 5.10 吸收和净化速率常数可能有助于使用分区模型预测环境命运 ( 7. ). 5.11 根据本指南（见指南），也可以考虑根据其他测试方法在生物体暴露后收集的组织来确定生物浓度 E1241 , E1688 , E2122页 , E2455 ，以及试验方法 E1706 ).

1.1 This guide describes procedures for obtaining laboratory data concerning bioconcentration of a test material added to dilution water—but not to food—by freshwater and saltwater fishes and saltwater bivalve mollusks using the flow-through technique. These procedures also should be useful for conducting bioconcentration tests with other aquatic species, although modifications might be necessary. 1.2 Other modifications of these procedures might be justified by special needs or circumstances. Although using appropriate procedures is more important than following prescribed procedures, the results of tests conducted using unusual procedures are not likely to be comparable to those of many other tests. The comparison of results obtained using modified and unmodified versions of these procedures might provide useful information concerning new concepts and procedures for conducting bioconcentration tests. 1.3 These procedures are applicable to all chemicals that can be measured accurately at the necessary concentrations in water and in appropriate tissues. Bioconcentration tests are usually conducted on individual chemicals but can be conducted on mixtures if appropriate measurements can be made. Some techniques described in this guide were developed for tests on non-ionizable organic chemicals (see 11.1.2.1 ) and might not apply to ionizable or inorganic chemicals. 1.4 Results of bioconcentration tests should usually be reported in terms of apparent steady-state and projected steady-state bioconcentration factors (BCFs) and uptake and depuration rate constants. Results should be reported in terms of whole body for fishes and in terms of total soft tissue for bivalve mollusks. For fishes and scallops consumed by humans, some results should also be reported in terms of the edible portion, especially if ingestion of the test material by humans is a major concern. For tests on organic and organometallic chemicals, the percent lipids of the tissue should be reported. 1.5 This guide is arranged as follows: Section Referenced Documents 2 Terminology 3 Summary of Guide 4 Significance and Use 5 Safety Precautions 7 Apparatus 6 Facilities 6.1 Construction Materials 6.2 Metering System 6.3 Test Chambers 6.4 Cleaning 6.4.4 Acceptability 6.5 Dilution Water 8 Requirements 8.1 Source 8.2 Treatment 8.3 Characterization 8.4 Test Material 9 General 9.1 Radiolabeled Material 9.2 Stock Solution 9.3 Test Concentration(s) 9.4 Test Organisms 10 Species 10.1 Size 10.2 Source 10.3 Care and Handling 10.4 Feeding 10.5 Disease Treatment 10.6 Holding 10.7 Acclimation 10.8 Quality 10.9 Procedure 11 Experimental Design 11.1 Dissolved Oxygen 11.2 Temperature 11.3 Loading 11.4 Beginning the Test 11.5 Care of Organisms 11.6 Feeding 11.7 Cleaning 11.8 Biological Data 11.9 Measurements on Test Solutions 11.10 Analytical Methodology 12 Acceptability of Test 13 Calculation of Results 14 Documentation 15 Keywords 16 1.6 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. Specific precautionary statements are given in Section 7 . This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. 1.8 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee. ====== Significance And Use ====== 5.1 A bioconcentration test is conducted to obtain information concerning the ability of an aquatic species to accumulate a test material directly from water. This guide provides guidance for designing bioconcentration tests on the properties of the test material so that each material is tested in a cost-effective manner. 5.2 Because steady-state is usually approached from the low side and the definition of apparent steady-state is based on a statistical hypothesis test, the apparent steady-state BCF will usually be lower than the steady-state BCF. With the variation and sample sizes commonly used in bioconcentration tests, the actual steady-state BCF will usually be no more than twice the apparent BCF. 5.3 When both are determined in the same test, the projected steady-state BCF will usually be higher than the apparent steady-state BCF because the models used to calculate the projected BCF assume that the BCF steadily increases until infinite time. 5.4 The BCFs and rates and extents of uptake and depuration will depend on temperature, water quality, the species and its size, physiological condition, age, and other factors ( 1 ) . 4 Although organisms are fed during tests, uptake by means of sorption onto food is probably negligible during tests. 5.5 Results of bioconcentration tests are used to predict concentrations likely to occur in aquatic organisms in field situations as a result of exposure under comparable conditions, except that mobile organisms might avoid exposure when possible. Under the experimental conditions, particulate matter is deliberately minimized compared to natural water systems. Exposure conditions for the tests may therefore not be comparable for an organic chemical that has a high octanol-water partition coefficient or for an inorganic chemical that sorbs substantially onto particulate matter. The amount of the test substance in solution is thereby reduced in both cases, and therefore the material is less available to many organisms. However, sorption might increase bioaccumulation by aquatic species that ingest particulate matter ( 2 ) , or food may be a more important source of residues in fish than water per se for stable neutral organic chemicals that have a Log K ow between 4 and 6 ( 3 ) . 5.6 Results of bioconcentration tests can be used to compare the propensity of different materials to be accumulated. Nonionizable organic chemicals can also be ranked for bioconcentration using correlations that have been reported between steady-state BCFs and physical–chemical properties, such as the octanol–water partition coefficient and solubility in water ( 4 ). However, when such predictions are impossible, exceed the demonstrated limits of the correlation, or might be otherwise questionable ( 1 , 5 ), a bioconcentration test may be necessary. 5.7 Results of bioconcentration tests can also be used to compare the abilities of different species to accumulate materials. At steady-state the concentration of a nonionizable organic chemical in individual organisms, and in various tissues within an organism, will probably be related to the concentration of lipids in the organisms and tissues ( 6 ). 5.8 Results of bioconcentration tests might be an important consideration when assessing hazard (see Guide E1023 ) or deriving water-quality criteria because consumer animals might be adversely affected by ingesting aquatic organisms that contain toxic materials. However, assessment of hazard to consumer organisms must take into account not only the quantity of material accumulated in tissues of aquatic organisms, but also the toxicity of the material to the consumer. Further, humans eat only certain portions of most aquatic organisms, whereas other predators often consume additional tissues. 5.9 Bioconcentration tests might be useful for studying structure–activity relationships between test materials, biological availability, metabolism of materials in aquatic organisms, and effects of various environmental factors on results of such tests. 5.10 Uptake and depuration rate constants might be useful for predicting environmental fate using compartmental models ( 7 ). 5.11 Tissues collected after organism exposures based on other testing methods might also be considered for determining bioconcentration according to this guide (see Guides E1241 , E1688 , E2122 , E2455 , and Test Method E1706 ).