Physiologically-relevant bioaccessibility measurements of inorganic contaminants

无机污染物的生理相关生物可及性测量

• 批准号: RGPIN-2018-04136
• 负责人: Meunier, Louise
• 金额: $ 1.89万
• 依托单位: Queen's University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=711875
• 关键词: Physiologically; relevant; bioaccessibility; measurements; inorganic

There are more than 22,000 contaminated sites in Canada [1], and exposure to soil contaminants poses risks to human health [2]. These risks are traditionally evaluated based on the total concentration of a contaminant in soil taken up from incidental ingestion, but this may overestimate the dose because non-soluble portions move through the digestive system without being absorbed into systemic circulation. In-vivo tests may provide physiologically-relevant data, but are costly and ethically problematic. Instead, bioaccessibility tests measure the portion of a contaminant available for absorption by the human body, and thus provide a physiologically-relevant measurement. When bioaccessibility is factored in, remediation efforts can target areas where risks have been identified. This approach allows for significant cost savings while protecting sensitive environments, which would otherwise be unnecessarily disturbed by overconservative remediation activities. Building on recent advances in this field, we propose to develop bioaccessibility tests that accurately reflect physiological conditions and yield representative results. The long-term goal of this program is to produce fully characterized and physiologically-relevant bioaccessibility data for risk assessors and policy makers to measure exposure to soil contaminants, (e.g. arsenic and new products, such as silver and nickel-alloy nanoparticles). To this end, we will focus on the following short-term objectives: (A) computational fluid dynamic simulations of gastrointestinal mixing parameters. These models will (B) be applied in-vitro to appropriately simulate digestive movement. Expanding on these results, we will (C) investigate the effects of mixed contaminants, such as polycyclic aromatic hydrocarbons (PAHs) on arsenic in soils, and adjust the chemical make-up of bioaccessibility test fluids. Finally, we propose to (D) study transport and epithelial absorption of colloids and small particles using an artificial porous medium, which may enhance the reliability of the data, especially in cases where comparisons with in-vivo results are not available. Ultimately, the vision of this research program is to render in-vivo tests obsolete. This program will train highly qualified engineers (2 PhD, 3 MSc, 5 UG), providing them with rigorous training to develop a solid expertise in the evaluation of risks from contaminated soils. The outcome of this proposed research is directly applicable to protecting human health, and will guide Canadians, environmental regulatory agencies, and risk assessors toward a targeted remediation of identified risk areas, resulting in less intrusive and more cost-effective redevelopment of contaminated sites.

加拿大有超过 22,000 个污染场地[1]，接触土壤污染物对人类健康构成风险[2]。传统上，这些风险是根据偶然摄入的土壤中污染物的总浓度来评估的，但这可能会高估剂量，因为不溶性部分会通过消化系统，而不会被吸收到体循环中。体内测试可以提供生理相关数据，但成本高昂且存在伦理问题。相反，生物可及性测试测量可被人体吸收的污染物部分，从而提供生理相关的测量。当考虑到生物可及性时，修复工作可以针对已识别出风险的区域。这种方法可以显着节省成本，同时保护敏感环境，否则敏感环境将受到过度保守的修复活动的不必要干扰。 基于该领域的最新进展，我们建议开发生物可及性测试，以准确反映生理条件并产生有代表性的结果。该计划的长期目标是为风险评估人员和政策制定者提供完全表征和生理相关的生物可及性数据，以测量土壤污染物（例如砷和新产品，例如银和镍合金纳米颗粒）的暴露程度。为此，我们将重点关注以下短期目标：（A）胃肠道混合参数的计算流体动力学模拟。这些模型将（B）应用于体外以适当模拟消化运动。扩展这些结果，我们将 (C) 研究混合污染物（例如多环芳烃 (PAH)）对土壤中砷的影响，并调整生物可及性测试液体的化学成分。最后，我们建议（D）使用人造多孔介质研究胶体和小颗粒的运输和上皮吸收，这可能会提高数据的可靠性，特别是在无法与体内结果进行比较的情况下。最终，该研究计划的愿景是淘汰体内测试。 该计划将培训高素质工程师（2 名博士、3 名硕士、5 名本科生），为他们提供严格的培训，以培养污染土壤风险评估方面的扎实专业知识。这项拟议研究的结果直接适用于保护人类健康，并将指导加拿大人、环境监管机构和风险评估人员对已确定的风险区域进行有针对性的修复，从而减少对污染场地的侵入，并提高其成本效益。