Quantitative Sustainability Assessment, Department of Environmental and Resource Engineering, Technical University of Denmark, Lyngby, Denmark.
Department of Environmental Health Sciences, School of Public Health, University of Michigan, Ann Arbor, Michigan, USA.
Environ Health Perspect. 2023 Mar;131(3):37016. doi: 10.1289/EHP11524. Epub 2023 Mar 29.
Regulatory toxicity values used to assess and manage chemical risks rely on the determination of the point of departure (POD) for a critical effect, which results from a comprehensive and systematic assessment of available toxicity studies. However, regulatory assessments are only available for a small fraction of chemicals.
Using experimental animal data from the U.S. Environmental Protection Agency's Toxicity Value Database, we developed a semiautomated approach to determine surrogate oral route PODs, and corresponding toxicity values where regulatory assessments are unavailable.
We developed a curated data set restricted to effect levels, exposure routes, study designs, and species relevant for deriving toxicity values. Effect levels were adjusted to chronic human equivalent benchmark doses (). We hypothesized that a quantile of the distribution could serve as a surrogate POD and determined the appropriate quantile by calibration to regulatory PODs. Finally, we characterized uncertainties around the surrogate PODs from intra- and interstudy variability and derived probabilistic toxicity values using a standardized workflow.
The distribution for each chemical was adequately fit by a lognormal distribution, and the 25th percentile best predicted the available regulatory PODs [, units]. We derived surrogate PODs for 10,145 chemicals from the curated data set, differentiating between general noncancer and reproductive/developmental effects, with typical uncertainties (at 95% confidence) of a factor of 10 and 12, respectively. From these PODs, probabilistic reference doses (1% incidence at 95% confidence), as well as human population effect doses (10% incidence), were derived.
In providing surrogate PODs calibrated to regulatory values and deriving corresponding toxicity values, we have substantially expanded the coverage of chemicals from 744 to 8,023 for general noncancer effects, and from 41 to 6,697 for reproductive/developmental effects. These results can be used across various risk assessment and risk management contexts, from hazardous site and life cycle impact assessments to chemical prioritization and substitution. https://doi.org/10.1289/EHP11524.
用于评估和管理化学风险的监管毒性值依赖于关键效应的起点 (POD) 的确定,这是对现有毒性研究进行全面系统评估的结果。然而,监管评估仅适用于一小部分化学物质。
利用美国环境保护署毒性值数据库中的实验动物数据,我们开发了一种半自动化方法来确定替代口服途径的 POD 以及在没有监管评估的情况下对应的毒性值。
我们开发了一个经过精心筛选的数据集,仅限于与推导毒性值相关的效应水平、暴露途径、研究设计和物种。我们将效应水平调整为慢性人类等效基准剂量 (BMD)。我们假设分布的分位数可以作为替代 POD,并通过与监管 POD 校准来确定合适的分位数。最后,我们通过内-和间-研究变异性来描述替代 POD 的不确定性,并使用标准化工作流程来推导概率毒性值。
对于每种化学物质,分布都可以通过对数正态分布很好地拟合,并且 25 分位数最好地预测了现有监管 POD[,单位]。我们从精选数据集中为 10,145 种化学物质推导了替代 POD,区分了一般非致癌和生殖/发育效应,典型不确定性(置信度为 95%)分别为 10 和 12 倍。从这些 POD 中,我们推导出了概率参考剂量(置信度为 95%时,1%的发生率)和人群效应剂量(置信度为 95%时,10%的发生率)。
通过提供与监管值校准的替代 POD 并推导出相应的毒性值,我们将一般非致癌效应的化学物质的覆盖率从 744 种大幅扩大到 8,023 种,将生殖/发育效应的化学物质的覆盖率从 41 种扩大到 6,697 种。这些结果可用于各种风险评估和风险管理情境,从危险场地和生命周期影响评估到化学品优先排序和替代。
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