Abstract
The heavy metal distributions in size-fractionated atmospheric particulate matters and the associated health risks were investigated in a typical mining and smelting area in Southwest China. The Cd, Cr, Cu, Pb, and Zn concentrations were 19.28, 44.48, 100.0, 554.0, and 601.8 ng/m3, respectively, in PM2.1; and 23.45, 60.99, 95.25, 559.3, and 813.7 ng/m3, respectively, in PM10. Enrichment factors of heavy metals indicated that anthropogenic sources of Cd, Cu, Pb, and Zn in the size-fractionated particles. The elevated concentrations of Cd, Cu, Pb, and Zn were dominantly enriched in submicron particles (DP < 1.1 μm), whereas Cr tended to be accumulated in coarse particles (2.1 < DP < 10 μm). The deposition concentrations for multiple heavy metals in the head airway region, tracheobronchial region, and alveolar regions were 321.07, 21.58, and 51.96 ng/h for children, and 634.49, 42.65, and 102.68 ng/h for adults, respectively. The coarse particles contributed the most to the deposition concentration of HMs in head region, whereas submicron particles had relative higher proportions in the alveolar region. Heavy metals, especially Pb, caused noncarcinogenic risk to the children as the hazard index was 4.45. Moreover, total carcinogenic risks of heavy metals (Cr, Cd, and Pb) were 4.33 × 10−5 and 7.58 × 10−5 for adults and children, respectively, indicating potential carcinogenic risks. Overall, the results of this study revealed high health risks to the residents living around the mining and smelting areas, especially the children. It was therefore urgent to control the emission of heavy metals in the atmosphere.
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References
Adewumi, A. J., & Laniyan, T. A. (2020). Contamination, sources, and risk assessments of metals in media from Anka artisanal gold mining area, Northwest Nigeria. Science of the Total Environment, 718, 137235.
Alam, K., Blaschke, T., Madl, P., Mukhtar, A., Hussain, M., Trautmann, T., et al. (2011). Aerosol size distribution and mass concentration measurements in various cities of Pakistan. Journal of Environmental Monitoring, 13(7), 1944–1952.
Anderson, J. O., Thundiyil, J. G., & Stolbach, A. (2012). Clearing the air: A review of the effects of particulate matter air pollution on human health. Journal of Medical Toxicology, 8(2), 166–175.
Bellinger, D. (1995). Neuropsychologic functions in children exposed to environmental lead. Epidemiology, 6, 101–103.
Betha, R., Behera, S. N., & Balasubramanian, R. (2013). Southeast Asian smoke haze: Fractionation of particulate bound elements and associated health risk. Environmental Science and Technology, 48, 4327–4335.
Cao, S. Z., Duan, X. L., Zhao, X. G., Chen, Y. T., Wang, B. B., Sun, C. Y., et al. (2016). Health risks of children’s cumulative and aggregative exposure to metals and metalloids in typical urban environment in China. Chemosphere, 147, 404–411.
Chang, Y., Huang, K., Deng, C., Zou, Z., Liu, S., & Zhang, Y. (2017). First long-term and near real-time measurement of atmospheric trace elements in Shanghai, China. Atmospheric Chemistry and Physics, 2017, 1–49.
CMEP (Ministry of Environmental Protection of China). (2012). Ambient air quality standards (GB3095-2012). Beijing: Environmental Science Press.
Csavina, J., Taylor, M. P., Félix, O., Rine, K. P., Eduardo Sáez, A., & Betterton, E. A. (2014). Size-resolved dust and aerosol contaminants associated with copper and lead smelting emissions: Implications for emission management and human health. Science of the Total Environment, 493, 750–756.
Dockery, D. W., & Pope, C. A. (1994). Acute respiratory effects of particulate air-pollution. Annual Review of Public Health, 15, 107–132.
Donaldson, K., Tran, C. L., & MacNee, W. (2002). Deposition and effects of fine and ultrafine particles in the respiratory tract. European Respiratory Monograph, 21, 77–92.
Duan, J. C., & Tan, J. (2013). Atmospheric heavy metals and arsenic in China: Situation, sources and control policies. Atmospheric Environment, 74, 93–101.
EU Parliament. (2008). Directive 2008/50/EC of the European parliament and of the council of 21 May 2008 on ambient air quality and cleaner air for Europe. Official Journal of the European Communities, 152, 1–44.
Galindo, N., Yubero, E., Nicolas, J. F., Varea, M., & Crespo, J. (2018). Characterization of metals in PM1 and PM10 and health risk evaluation at an urban site in the western Mediterranean. Chemosphere, 201, 243–250.
Gholizadeh, A., Salmani, M. H., Ebrahimi, A. A., Hosseini, S. S., Ehrampoush, M. H., Miri, M., et al. (2018). Improved power density and Cr/Pb removal using ozone in a microbial desalination cell. Environmental Chemistry Letters, 16, 1477–1485.
Ghosh, S., Rabha, R., Chowdhury, M., & Padhy, P. K. (2018). Source and chemical species characterization of PM10 and human health risk assessment of semi-urban, urban and industrial areas of West Bengal, India. Chemosphere, 207, 626–636.
Goix, S., Ponit, D., Oliva, P., Polve, M., Duprey, J. L., Mazurek, H., et al. (2011). Influence of source distribution and geochemical composition of aerosols on children exposure in the large polymetallic mining region of the Bolivian Altiplano. Science of the Total Environment, 412–413, 170–184.
Hao, Y. F., Meng, X. P., Yu, X. P., Lei, M. L., Li, W. J., Shi, F. T., et al. (2018). Characteristics of trace elements in PM2.5 and PM10 of Chifeng, northeast China: Insights into spatiotemporal variations and sources. Atmospheric Research, 213, 550–561.
Hinwood, A., Callan, A. C., Heyworth, J., McCafferty, P., & Sly, P. D. (2014). Children’s personal exposure to PM10 and associated metals in urban, rural and mining activities areas. Chemosphere, 108, 125–153.
Huang, C. L., Bao, L. J., Luo, P., Wang, Z. Y., Li, S. M., & Zeng, E. Y. (2016). Potential health risk for residents around a typical e-waste recycling zone via inhalation of size-fractionated particle-bound heavy metals. Journal of Hazardous Materials, 317, 449–456.
Huang, L., Bai, Y. H., Ma, R. Y., Zhuo, Z. M., & Chen, L. (2019). Winter chemical partitioning of metals bound to atmospheric fine particles in Dongguan, China, and its health risk assessment. Environmental Science and Pollution Research, 26, 136664–136675.
ICRP (International Commission on Radiological Protection). (2006). Publication 66: Human respiratory tract model for radiological protect. Annal of the ICRP, 24, 1–3.
Kamunda, C., Mathuthu, M., & Madhuku, M. (2016). Health risk assessment of heavy metals in soils from Witwatersrand gold mining basin, South Africa. International Journal of Environmental Research and Public Health, 13(7), 2–11.
Laniyan, T. A., & Adewumi, A. J. (2020). Potential ecological and health risks of toxic metals associated with artisanal mining contamination in Ijero, southwest Nigeria. Journal of Environmental Science and Health, Part A Environmental Science, 55, 858–877.
Li, K. X., Liang, T., & Wang, L. Q. (2016a). Risk assessment of atmospheric heavy metals exposure in Baotou, a typical industrial city in Northern China. Environmental Geochemistry and Health, 38, 843–853.
Li, Y. Y., Wang, H. B., Wang, H. J., Yin, F., Yang, X. Y., & Hu, Y. J. (2016b). Heavy metal pollution in vegetables grown in the vicinity of a multiple metal mining area in Gejiu, China. Environmental Science and Pollution Research, 21, 12569–12582.
Liu, X. L., Ouyang, W. Y., Shu, Y. L., Tian, Y. Z., Feng, Y. C., Zhang, T., et al. (2019). Incorporating bioaccessibility into health risk assessment of heavy metals in particulate matter originated from different sources of atmospheric pollution. Environmental Pollution, 254, 113113–113125.
Lyu, Y., Zhang, K., Chai, F. H., Cheng, T. T., Yang, Q., Zheng, Q. L., et al. (2017). Atmospheric size-resolved trace elements in a city affected by non-ferrous metal smelting: Indications of respiratory deposition and health risk. Environmental Pollution, 224, 559–571.
Ma, C., Liu, F. Y., Hu, B., Wei, M. B., Zhao, J. H., & Zhang, H. Z. (2019). Quantitative analysis of lead sources in wheat tissue and grain under different lead atmospheric deposition areas. Environmental Science and Pollution Research, 26, 36710–36719.
Masiol, M., Squizzato, S., Cecceato, D., & Pavoni, B. (2015). The size distribution of chemical elements of atmospheric aerosol at a semi-rural coastal site in Venice (Italy), the role of atmospheric circulation. Chemosphere, 119, 400–406.
Mbengue, S., Alleman, L. Y., & Flament, P. (2014). Size-distributed metallic elements in submicronic and ultrafine atmospheric particles from urban and industrial areas in northern France. Atmospheric Research, 135–136, 35–47.
Mbengue, S., Alleman, L. Y., & Flament, P. (2017). Metal-bearing fine particle sources in a coastal industrialized environment. Atmospheric Research, 183, 202–211.
Mohammed, M. O. A., Song, W. W., Wan, L., Wen, M. A., Long, L. I., Fan, Y., et al. (2016). Potential toxicological and cardiopulmonary effects of PM2.5 exposure and related mortality: Findings of recent studies published during 2003–2013. Biomedical and Environmental Sciences, 29, 66–79.
Mohiuddin, K., Strezov, V., Nelson, P. F., & Stelcer, E. (2014). Characterization of trace metals in atmospheric particles in the vicinity of iron and steelmaking industries in Australia. Atmospheric Environment, 83, 72–79.
Pan, Y., Tian, S., Li, X., Sun, Y., Li, Y., Wentworth, G. R., et al. (2015). Trace elements in particulate matter from metropolitan regions of Northern China: Sources, concentrations and size distributions. Science of the Total Environment, 537, 9–22.
Pope, C. A., III, Burnett, R. T., Thun, M. J., Calle, E. E., Krewski, D., Ito, K., et al. (2002). Lung cancer, cardiopulmonary mortality, and long-term exposure to fine particulate air pollution. The Journal of the American Medical Association, 287, 1132–1141.
Qi, L., Zhang, Y. F., Ma, Y. H., Chen, M. D., Ge, X. L., Ma, Y., et al. (2016). Source identification of trace elements in the atmosphere during the second Asian Youth Games in Nanjing, China: Influence of control measures on air quality. Atmospheric Pollution Research, 7, 547–556.
Radhi, M., Box, M. A., Box, G. P., & Cohen, D. D. (2010). Size resolved chemical composition of the September 2009 Sydney dust storm. Air Quality and Climate Change, 10, 25–29.
Ran, J. W., Ning, P., Sun, X., & Liang, D. X. (2019). Heavy metal pollution characteristics and potential risks of soil and crops in Gejiu, Yunnan. Environmental Monitoring in China, 35, 62–68.
RIVM, (National Institute National Institute for Public Health and the Environment). (2002). Multiple path particle dosimetry model (MPPD v 1.0): A model for human and rat airway particle dosimetry, Bilthoven, The Netherlands. RIVA Report 65001003.
Sanchez-soberon, F., Rovira, J., Mari, M., Sierra, J., Nadal, M., Domingo, J. L., et al. (2015). Main components and human health risks assessment of PM10, PM2.5, and PM1 in two areas influenced by cement plants. Atmospheric Environment, 120, 109–116.
Shaughnessy, W. J., Venigalla, M. M., & Trump, D. (2015). Health effects of ambient levels of respirable particulate matter (PM) on healthy, young-adult population. Atmospheric Environment, 123, 102–111.
Sutherland, R. A. (2000). A comparison of geochemical information obtained from two fluvial bed sediment fractions. Environmental Geology, 39(3–4), 330–341.
Tan, J. H., Duan, J. C., Zhen, N. J., He, K. B., & Hao, J. M. (2016). Chemical characteristics and source of size-fractionated atmospheric particle in haze episode in Beijing. Atmospheric Research, 167, 24–33.
Tian, S. H., Liang, T., & Li, K. X. (2019). Fine road dust contamination in a mining area presents a likely air pollution hotspots and threat to human health. Environment International, 128, 201–209.
Ulnikovic, V. P., Kurilic, S. M., & Staletovic, N. (2020). Air quality benefits from implementing best available techniques in copper mining and smelting complex Bor (Serbia). Water, Air, and Soil pollution, 231, 160–174.
USEPA. (1989). Human health evaluation manual (Part A). EPA/540/1-89/002. Risk assessment guidance for superfund, Vol. I. Washington, DC: US Environmental Protection Agency, Office of Emergency and Remedial Response.
USEPA. (1998). Environmental Protection Agency, toxicological review of hexavalent chromium. Washington, DC: National Center for Environmental Assessments, Office of Research and Development.
USEPA. (2001). Risk assessment guidance for superfund: volume III-Part a, Process for conducting probabilistic risk assessment. EPA 540-R-02-002. Washington, DC: Office of Emergency and Remedial Response.
USEPA. (2007). Microwave assisted digestion of sediments, sludges, soils and oils (3051a). Test Methods For Evaluating Solid Waste. Washington DC: US Environmental Protection Agency. https://www.epa.gov/sites/production/files/2015-12/documents/3051a.pdf.
USEPA. (2011). Exposure factors handbook (2011th ed.). Washington, DC: National Center for Environmental Assessment.
Voutsa, D., & Samara, C. (2002). Labile and bio-accessible fractions of heavy metals in the airborne particulate matter from urban and industrial areas. Atmospheric Environment, 36, 3583–3590.
Wang, F., Zhou, Y. Y., Meng, D., Han, M. M., & Jia, C. Q. (2018). Heavy metal characteristics and health risk assessment of PM2.5 in three residential homes during winter in Nanjing, China. Building and Environment, 143, 339–348.
Wang, J., Hu, Z. M., Chen, Y. Y., Chen, Z. L., & Xu, S. Y. (2013). Contamination characteristics and possible sources of PM10 and PM2.5 in different functional areas of Shanghai, China. Atmospheric Environment, 68, 221–229.
Wang, J., Su, J. W., Li, Z. G., Liu, B. X., Cheng, G. H., Jiang, Y. H., et al. (2019a). Source apportionment of heavy metal and their health risks in soil dustfall-plant system nearby a typical non-ferrous metal mining area of Tongling, Eastern China. Environmental Pollution, 254, 113089–113099.
Wang, S. B., Yan, Q. S., Zhang, R. Q., Jiang, N., Yin, S. S., & Ye, H. Q. (2019b). Size-fractionated particulate elements in an inland city of China: Deposition flux in human respiratory, health risks, source apportionment, and dry deposition. Environmental Pollution, 247, 515–523.
Wedepohl, H. K. (1995). The composition of the continental crust. Geochimica et Cosmochimica Acta, 59(7), 1217–1232.
WHO. (2000). Air quality guidelines for Europe, seconded. Copenhagen: The Regional Office for Europe of the World Health Organization.
Widziewicz, K., & Loska, K. (2016). Metal induced inhalation exposure in urban population: A probabilistic approach. Atmospheric Environment, 128, 198–207.
Widziewicz, K., Rogula-Kozlowska, W., & Loska, K. (2016). Cancer risk from arsenic and chromium species bound to PM2.5 and PM1—Polish case study. Atmospheric Pollution Research, 7, 884–894.
Xie, J. J., Yuan, C. G., Shen, Y. W., Xie, J., He, K. Q., Zhu, H. T., et al. (2019). Bioavailability/speciation of arsenic in atmospheric PM2.5 and their seasonal variation: A case study in Baoding city, China. Ecotoxicology and Environmental Safety, 169, 487–495.
Xing, W. Q., Zhao, Q., Scheckel, K. G., Zheng, L. R., & Li, L. P. (2019). Inhalation bioaccessibility of Cd, Cu, Pb, and Zn and speciation of Pb in particulate matter fractions from areas with different pollution characteristics in Henan Province, China. Ecotoxicology and Environmental Safety, 175, 192–200.
Xue, H. Q., Liu, G. J., Zhang, H., Hu, R. Y., & Wang, X. (2019). Similarities and differences in PM10 and PM2.5 concentrations, chemical compositions and sources in Hefei City, China. Chemosphere, 220, 760–765.
Yang, X., Zhou, X. T., Kao, T., Strezov, V., Nelson, P., Evan, T., et al. (2019). Characterization of size resolved atmospheric particles in the vicinity of iron and steelmaking industries in China. Science of the Total Environment, 694, 133534–133545.
Yunnan Yearbook. (2019). Yunnan Almanac Press, p. 25.
Zeng, M., Guo, R., Yang, S. M., Zhang, D. Y., Wang, L. X., Yin, F. Y., et al. (2019). Heavy metal pollution and ecological risk assessment in agricultural production areas. Soils and Crops, 8, 85–92.
Zhang, K., Chai, F. H., Zheng, Z. L., Yang, Q., Zhong, X. C., Fomba, K. W., et al. (2018). Size distribution and source of heavy metals in particulate matter on the lead and zinc smelting affected area. Journal of Environmental Sciences, 9, 147–153.
Zhang, K., Yang, J. J., Wang, Y. Y., Xia, Y., Liu, S. H., & Zhang, R. X. (2020). All-region human health risk assessment of Cr(VI) in a coal chemical plant based on kriging. Polish Journal of Environmental Studies, 29, 429–439.
Zhou, Y. H., Liu, Y. Y., & Li, G. W. (2017). The hydrogeological conditions and water damage control measure of Kafang Ming area, Gejiu, Yunnan Province. Modern Mining, 579(308–311), 314. (In Chinses).
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This work was supported by the National Key Technology Research and Development Program of China [Grant Number 2018YFC1800104].
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Guo, G., Zhang, D. & Wang, Y. Characteristics of heavy metals in size-fractionated atmospheric particulate matters and associated health risk assessment based on the respiratory deposition. Environ Geochem Health 43, 285–299 (2021). https://doi.org/10.1007/s10653-020-00706-z
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DOI: https://doi.org/10.1007/s10653-020-00706-z