Prediction of the biodegradation of chemicals using OECD QSAR Toolbox software

Khalidya Khizbulaevna Khamidulina, E. V. Tarasova, Mikhail L. Lastovetsky
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Abstract

Introduction. The development of integrated approaches to testing, assessment of the hazard and exposure risk of chemicals on human health and the environment is one of the priorities of preventive toxicology. An integrated approach involves various combinations of methods in silico, in chemico, in vitro, ex vivo, in vivo for hazard assessment. In the Russian Federation, in silico methods are often perceived with skepticism, mainly due to the lack of their legal status, weak methodological base and insufficient training of specialists. In order to expand the methodological base, the possibility of predicting the stability of chemicals in biotic conditions using the OECD QSAR Toolbox software was studied. Material and methods. The OECD QSAR Toolbox software version 4.4.1., OECD guidelines on the assessment of biodegradation of chemicals. Results. The world community and the OECD have developed and implemented a three-level system for chemicals biodegradation testing, which includes tests for readily biodegradation (OECD Guidelines 301 A, 301 B, 301 C, 301 D, 301 E, 301 F, 306, 310), tests to determine the potential biodegradability (OECD Guidelines 302 A, 302 B, 302 C, 304 A) and model systems tests (OECD Guidelines 303 A, 303 B). To test the capabilities of the program, 24 endpoints were selected. They are the determination of biodegradability (%) by BOD, DOC, CO2, CH4 releases in OECD tests 301 A, 301 B, 301 C, 301 D, 302 C, 302 B, biodegradability (%) in sediments and soil, bioconcentration factors for more than 100 organic chemicals of various structures. The parameters were calculated using the analog method, followed by mandatory interpretation of the data obtained by an expert. When predicting the biodegradability of chemicals, it is necessary to perform a series of calculations using different tests (OECD tests 301 A, 301 B, 301 C, 301 D, 301 E, 302 B are preferred) and grouping methods followed by a comprehensive assessment of the results obtained, taking into account not only the structural similarity of substances and analogues, but also the quality of the experimental data used. When predicting biodegradability by BOD values, it is advisable to use the OECD 301 C test. The proportion of tested substances whose biodegradability could be estimated by BOD values is about 50% in the OECD 301 C test, which is primarily due to the presence of a significant amount of experimental data. The calculation of bioconcentration factors seems to be promising. For about 45% of the tested substances, it was possible to calculate bioconcentration coefficients with good correlation with experimental data. Biodegradation in soil (% and half-life) can be predicted only for a very limited range of compounds (10% of the tested substances), which is due to the difficulty of selecting structurally similar analogues with experimental data. The method is not applicable for predicting the biodegradation of salts, organometallic compounds, polymer molecules and mixed products. Conclusion. The Russian Register of Potentially Hazardous Chemical and Biological Substances has developed a methodological guide for predicting the stability of chemicals in biotic conditions using the OECD QSAR Toolbox software. The document presents algorithms for calculating biodegradability (%) according to OECD tests 301, 302, 303; BOD, bioconcentration factors and biodegradability (%) in soil.
使用 OECD QSAR 工具箱软件预测化学品的生物降解情况
导言。开发综合方法来测试、评估化学品对人类健康和环境的危害和暴露风险,是预防毒理学的优先事项之一。综合方法包括硅学、化学、体外、体内和体外危害评估方法的各种组合。在俄罗斯联邦,人们往往对硅学方法持怀疑态度,主要原因是这些方法缺乏法律地位、方法基础薄弱以及专家培训不足。为了扩大方法论基础,我们研究了使用 OECD QSAR 工具箱软件预测化学品在生物条件下稳定性的可能性。材料和方法经合组织 QSAR 工具箱软件 4.4.1 版、经合组织化学品生物降解评估指南。结果。国际社会和经济合作与发展组织(OECD)制定并实施了一套三级化学品生物降解测试系统,包括容易生物降解测试(OECD 准则 301 A、301 B、301 C、301 D、301 E、301 F、306、310)、确定潜在生物降解性的测试(OECD 准则 302 A、302 B、302 C、304 A)和模型系统测试(OECD 准则 303 A、303 B)。为测试程序的能力,选择了 24 个终点。它们是经合组织测试 301 A、301 B、301 C、301 D、302 C、302 B 中通过 BOD、DOC、CO2、CH4 释放量确定的生物降解性(%),沉积物和土壤中的生物降解性(%),以及 100 多种不同结构的有机化学品的生物富集因子。这些参数采用模拟法计算,然后由专家对获得的数据进行强制性解释。在预测化学品的生物降解性时,有必要使用不同的测试(首选经合组织测试 301 A、301 B、301 C、301 D、301 E、302 B)和分组方法进行一系列计算,然后对所得结果进行综合评估,不仅要考虑物质和类似物的结构相似性,还要考虑所用实验数据的质量。通过生化需氧量值预测生物降解性时,建议使用 OECD 301 C 测试。在 OECD 301 C 试验中,可通过生化需氧量估算生物降解性的受试物质比例约为 50%,这主要是由于存在大量的实验数据。生物富集因子的计算似乎很有前景。对于约 45% 的受测物质,可以计算出与实验数据具有良好相关性的生物富集系数。只有非常有限的化合物(占测试物质的 10%)可以预测其在土壤中的生物降解(百分比和半衰期),这是因为很难根据实验数据选择结构相似的类似物。该方法不适用于预测盐类、有机金属化合物、聚合物分子和混合产物的生物降解。结论俄罗斯潜在危险化学物质和生物物质登记处已开发出一套方法指南,用于使用 OECD QSAR 工具箱软件预测化学品在生物条件下的稳定性。该文件介绍了根据经合组织测试 301、302 和 303 计算生物降解性(%)的算法;土壤中的生化需氧量、生物富集系数和生物降解性(%)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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