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印度西南部一城市地区颗粒物及其相关金属毒性的特征描述。

Characterization of particulate matter and its related metal toxicity in an urban location in South West India.

机构信息

Department of Chemistry, University of Pune, Pune 411 007, India.

出版信息

Environ Monit Assess. 2013 Sep;185(9):7365-79. doi: 10.1007/s10661-013-3106-6. Epub 2013 Feb 3.

DOI:10.1007/s10661-013-3106-6
PMID:23377774
Abstract

This study reports the quantification of the toxicity of particulate matter (PM)-bound metals and their possible associated risks to human health. For assessment of PM, 24-h samples of PM(10) and PM2.5 were collected by Mini Vol-TAS sampler at an urban site of Pune. Samples were sequentially extracted with ultrapure water and concentrated HNO3 and analyzed for "soluble" and "total" metals. Factor analysis identified the resuspension of road dust due to traffic, biomass burning, construction activities, and wind-blown dust as possible sources that played an important role for overall pollution throughout the year. Water-soluble proportion was found to be ≤ 20 % for Cr, Co, Fe, and Al; ≥ 50 % for Sr, Cd, Ca, and Zn; and a substantial proportion (25-45 %) for Mn, Ba, K, Na, Ni, Mg, Cu, and Pb metals in PM(10). For PM2.5, the water-soluble proportion was ≤ 20 % for Fe, Co, Ni, Cr, and Al, while Sr, K, and Cd were mostly soluble (> 50 %) and Cu, Ba, Mn, Ca, Zn, Pb, Na, and Mg were substantially soluble (25-45 %). In the present study, among the toxic metals, Cd and Pb show higher concentration in the soluble fraction and thus represent the higher bioavailability index and especially are harmful to the environment and exposed person. Risk calculations with a simple exposure assessment method showed that the cancer risks of the bioavailable fractions of Cr, Cd and Ni were greater than the standard goal.

摘要

本研究报告了颗粒物(PM)结合金属的毒性及其对人类健康可能产生的相关风险的量化评估。为了评估 PM,我们在浦那的一个城市站点使用 Mini Vol-TAS 采样器采集了 24 小时的 PM(10)和 PM2.5 样本。这些样本依次用超纯水和浓 HNO3 进行提取,并分析了“可溶性”和“总”金属。因子分析确定了交通、生物质燃烧、建筑活动和扬尘引起的道路扬尘再悬浮是全年整体污染的重要来源。结果发现,Cr、Co、Fe 和 Al 的水溶性比例≤20%;Sr、Cd、Ca 和 Zn 的水溶性比例≥50%;Mn、Ba、K、Na、Ni、Mg、Cu 和 Pb 的水溶性比例在 PM(10)中占相当大的比例(25-45%)。对于 PM2.5,Fe、Co、Ni、Cr 和 Al 的水溶性比例≤20%,而 Sr、K 和 Cd 主要是可溶性的(>50%),Cu、Ba、Mn、Ca、Zn、Pb、Na 和 Mg 的水溶性比例也相当高(25-45%)。在本研究中,在有毒金属中,Cd 和 Pb 在可溶性部分中的浓度更高,因此具有更高的生物利用度指数,特别是对环境和暴露人群具有危害性。采用简单的暴露评估方法进行风险计算表明,Cr、Cd 和 Ni 的生物可利用部分的癌症风险大于标准目标。

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