Physicochemical insights into the environmental risks of metals

对金属环境风险的物理化学见解

• 批准号: RGPIN-2014-05352
• 负责人: Wilkinson, Kevin
• 金额: $ 4.44万
• 依托单位: Université de Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=668583
• 关键词: Physicochemical; insights; into; environmental; risks

Assessments of the ecological risk (ERA) of organic chemicals typically include determinations of their persistence, bioaccumulation and toxicity. For inorganic chemicals such as metals and nanomaterials, this approach is clearly an oversimplification. For example, trace metal speciation measurements, including the dynamics of complexation reactions are often critical in environmental systems. Similarly, for emerging contaminants such as nanoparticles, the stability of the colloidal systems (with respect to agglomeration) and the (often non-equilibrium) reactions leading to particle dissolution are certain to strongly influence their bioavailability. Therefore, the overall goal of this research program is to increase our understanding of the molecular underpinnings of environmental risk by carefully examining the mechanisms leading to the biological uptake or mobility of several emerging contaminants. Experiments are designed to lead to insights that will help improve existing models of environmental fate. Research will be focused on three key areas of importance that are required to better quantify the metal exposures in the environment: (i) determining the aging of novel metal containing materials (roughly persistence); (ii) developing better insight into the bioaccumulation of metal complexes and metallic nanoparticles and (iii) evaluating the mass transport of some emerging contaminants. Insights into metal toxicity (hazard), although not a main focus of this research programme, will nonetheless be acquired during transcriptome sequencing studies of metal bioavailability. **Discovery grant funding will be used to gain fundamental insight into key biophysicochemical processes affecting ecological risk. For the trace metals, our focus will be on determining the role of chemical speciation on trace metal bioavailability with a particular emphasis on the contribution of metal complexes. Projects will be focused on the interesting and economically important lanthanide series of metals. We anticipate that their (primarily) trivalent nature and their strong capacity to bind organic matter will lead to the discovery of important exceptions to predictive models such as the Biotic Ligand Model. Analytical techniques will be optimized so that chemical speciation can be accurately measured. The biouptake of the hydrophilic metal complexes, generally neglected in predictive models such as the Biotic ligand model, will be studied thoroughly. **In some cases, the bioavailability of toxic chemicals may be limited by the transfer of the compound from the water, soil or sediment to the surface of the biological organism (mass transport limitation). This implies that it is often just as important to understand the physical properties of chemicals as it is to understand their intrinsic chemical reactivity. We anticipate that for certain chemicals (larger, slowly diffusing chemicals such as nanomaterials) and in certain environments (biofilms, soils, sediments), mass transport will be limiting with the implication that dynamic models will be necessary in order to obtain accurate predictions of bioavailability. For contaminants such as nanomaterials, our work will be designed to carefully quantify dynamic and often non-equilibrium processes such as particle agglomeration and dissolution. Novel nanoparticle characterization techniques such single particle ICP-MS or analytical ultracentrifugation will be explored with the goal of measuring particle/agglomerate at their predicted low concentrations. Emphasis will be placed on improving our mechanistic understanding of these problems of environmental function so that as new (metal-based) contaminants of economic interest are identified, their ERA can be readily prioritized.

有机化学品的生态风险评估通常包括确定其持久性、生物累积性和毒性。 对于金属和纳米材料等无机化学品，这种方法显然过于简单化。例如，痕量金属形态测量，包括络合反应的动力学，在环境系统中往往是至关重要的。类似地，对于新出现的污染物，如纳米颗粒，胶体系统的稳定性（相对于团聚）和（通常是非平衡）导致颗粒溶解的反应肯定会强烈影响其生物利用度。因此，这项研究计划的总体目标是通过仔细研究导致几种新出现的污染物的生物吸收或流动性的机制，增加我们对环境风险的分子基础的理解。实验的目的是引导洞察力，这将有助于改善现有的环境命运模型。研究将集中在三个重要的关键领域，以更好地量化环境中的金属暴露：（一）确定新的含金属材料的老化（大致持久性）;（二）更好地了解金属络合物和金属纳米颗粒的生物累积性;（三）评估一些新出现的污染物的质量迁移。深入了解金属毒性（危害），虽然不是本研究计划的主要重点，但将在金属生物利用度的转录组测序研究中获得。** 发现补助金资金将用于对影响生态风险的关键生物农药化学过程进行基本了解。对于微量金属，我们的重点将是确定微量金属生物利用度的化学形态的作用，特别强调金属络合物的贡献。 项目将集中在有趣的和经济上重要的镧系金属。我们预计，它们（主要是）三价的性质和它们结合有机物的强大能力将导致发现重要的例外预测模型，如生物配体模型。 将优化分析技术，以便准确测量化学形态。亲水性金属络合物的生物摄取，通常被忽视的预测模型，如生物配体模型，将进行彻底的研究。** 在某些情况下，有毒化学品的生物利用度可能受到化合物从水、土壤或沉积物转移到生物有机体表面的限制（质量迁移限制）。这意味着了解化学品的物理性质与了解其内在的化学反应性通常同样重要。 我们预计，对于某些化学品（较大的，缓慢扩散的化学品，如纳米材料）和某些环境（生物膜，土壤，沉积物），质量传输将是有限的，这意味着动态模型将是必要的，以获得准确的生物利用度的预测。对于纳米材料等污染物，我们的工作将被设计为仔细量化动态和经常非平衡过程，如颗粒团聚和溶解。新型纳米颗粒表征技术，如单颗粒ICP-MS或分析超离心将探索与测量颗粒/团聚体在其预测的低浓度的目标。重点将放在提高我们对这些环境功能问题的机械理解，以便确定新的（金属基）污染物的经济利益，他们的ERA可以很容易地优先考虑。