中国宁夏北部地区玉米、土壤和灌溉水中的潜在有毒元素 (PTE) 水平以及通过食用玉米带来的健康风险。

Potentially toxic element (PTE) levels in maize, soil, and irrigation water and health risks through maize consumption in northern Ningxia, China.

机构信息

School of Civil and Hydraulic Engineering, Ningxia University, Yinchuan, 750021, China.

School of Physics and Electronic-Electrical Engineering, Ningxia University, Yinchuan, 750021, China.

出版信息

BMC Public Health. 2020 Nov 16;20(1):1729. doi: 10.1186/s12889-020-09845-5.

DOI:10.1186/s12889-020-09845-5

PMID:33198713

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7670719/

Abstract

BACKGROUND

Industrial and agricultural activities result in elevated levels of potentially toxic elements (PTEs) in the local environment. PTEs can enter the human body through the food chain and pose severe health risks to inhabitants. In this study, PTE levels in maize, soil, and irrigation water were detected, and health risks through maize consumption were evaluated.

METHODS

Maize, soil, and irrigation water samples were collected in northern Ningxia, China. Inductively coupled plasma-optical emission spectrometry was applied to determine the contents of six PTEs. Bioaccumulation factor was used to reflect the transfer potential of a metal from soil to maize. Health risks associated with maize consumption were assessed by deterministic and probabilistic estimation. Sensitivity analysis was performed to determine variables that pose the greatest effect on health risk results.

RESULTS

The levels of Pb and Cr in maize exceeded the standards, while the PTE levels in soil and irrigation water did not exceed the corresponding standards. The bioaccumulation factor values of the six PTEs in maize were all lower than 1 and followed the order of Cd > Zn = As > Cr > Cu > Pb. The hazard index (0.0986) was far less than 1 for all inhabitants implying no obvious non-carcinogenic risk. The carcinogenic risk value was 3.261 × 10, which was lower than the maximum acceptable level of 1 × 10 suggested by United States Environmental Protection Agency (USEPA). Females were at greater risk than males, and the age group of below 20 years had the greater risk among all the groups evaluated. Approximately 0.62% of inhabitants exceeded the level for non-carcinogenic risk, while 8.23% exceeded the level for carcinogenic risk. The As concentration and daily intake of maize contributed 35.8, and 29.4% for non-carcinogenic risk results as well as 61.0 and 18.5% for carcinogenic risk results.

CONCLUSIONS

Maize was contaminated by Pb and Cr, whereas the associated soil and irrigation water were not contaminated by PTEs. Inhabitants would not suffer obvious harmful health risks through maize consumption. Arsenic level and daily intake of maize were the most sensitive factors that impact health risks.

摘要

背景

工业和农业活动导致当地环境中潜在有毒元素（PTEs）的含量升高。PTEs 可以通过食物链进入人体，对居民健康造成严重威胁。本研究检测了宁夏北部地区玉米、土壤和灌溉水中的 PTE 水平，并评估了通过食用玉米摄入 PTE 带来的健康风险。

方法

采集宁夏北部的玉米、土壤和灌溉水样品。采用电感耦合等离子体-光学发射光谱法测定六种 PTE 的含量。生物富集系数用于反映金属从土壤向玉米转移的潜力。通过确定性和概率估计评估与食用玉米相关的健康风险。进行敏感性分析以确定对健康风险结果影响最大的变量。

结果

玉米中 Pb 和 Cr 的含量超过标准，而土壤和灌溉水中的 PTE 含量未超过相应标准。玉米中六种 PTE 的生物富集系数均低于 1，顺序为 Cd>Zn=As>Cr>Cu>Pb。所有居民的危害指数（0.0986）远小于 1，表明没有明显的非致癌风险。致癌风险值为 3.261×10，低于美国环保署（USEPA）建议的最大可接受水平 1×10。女性的风险大于男性，评估的所有群体中，20 岁以下年龄组的风险更大。约有 0.62%的居民超过非致癌风险水平，8.23%的居民超过致癌风险水平。As 浓度和玉米的日摄入量对非致癌风险结果的贡献率分别为 35.8%和 29.4%，对致癌风险结果的贡献率分别为 61.0%和 18.5%。

结论

玉米受到 Pb 和 Cr 的污染，而相关土壤和灌溉水未受到 PTE 污染。居民通过食用玉米不会遭受明显的有害健康风险。砷水平和玉米的日摄入量是影响健康风险的最敏感因素。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7728/7670719/ac8afa947c2f/12889_2020_9845_Fig1_HTML.jpg

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中国宁夏北部地区玉米、土壤和灌溉水中的潜在有毒元素 (PTE) 水平以及通过食用玉米带来的健康风险。

Potentially toxic element (PTE) levels in maize, soil, and irrigation water and health risks through maize consumption in northern Ningxia, China.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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