Spatial distribution of trace elements (As, Cd, Ni, Pb) from PM10 aerosols and human health impact assessment in an Eastern European country, Romania

被引:0
作者
Katalin Bodor
Zsolt Bodor
Róbert Szép
机构
[1] University of Pécs,Faculty of Natural Sciences, Doctoral School of Chemistry
[2] Sapientia Hungarian University of Transylvania,Faculty of Economics, Socio
[3] Institute for Research and Development for Hunting and Mountain Resources, Human Sciences and Engineering, Department of Bioengineering
来源
Environmental Monitoring and Assessment | 2021年 / 193卷
关键词
PM; Trace elements; Health impact assessment; Principal component analysis; Risk analysis;
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中图分类号
学科分类号
摘要
In the present study, the concentrations of trace elements in PM10 were determined and analyzed at 115 monitoring stations in Romania throughout the period 2009–2018. The spatiotemporal distribution of trace element concentrations of PM10, the source apportionment and health impact assessment, was carried out. The results showed a very high multi-annual mean concentration for PM10 and trace elements as well. The multiannual average concentration of PM10 was higher by 29.75% than the World Health Organization recommendation. All studied air pollutants showed a decreasing trend during the studied years, showing with 17.84%, 50.21%, 43.36%, 11.27%, and 72.09% lower values for PM10, As-, Cd-, Ni-, and Pb-, respectively, due to environmental regulations. To assess the human health impact, the hazard quotient (HQ) and cancer risk (CR) were calculated using the health risk model developed by the US Environmental Protection Agency (EPA). The Cd and Ni might present a non-carcinogenic risk to both adults and children; however, the hazard quotient values are higher than the safe limit, with 9.53 and 1.93, respectively. In addition, our study results revealed that the inhalation of As, Cd and the dermal absorption of all studied trace elements were considered as the most important risk factors for developing cancer, especially in case of adults.
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