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Human Health Risks Associated with Potentially Harmful Elements from Urban Soils of Hamedan City, Iran | ||
Pollution | ||
مقاله 16، دوره 7، شماره 3، مهر 2021، صفحه 709-722 اصل مقاله (1017.13 K) | ||
نوع مقاله: Original Research Paper | ||
شناسه دیجیتال (DOI): 10.22059/poll.2021.318496.1015 | ||
نویسندگان | ||
Mahsa Tashakor* ؛ Soroush Modabberi | ||
School of Geology, College of Science, University of Tehran, P.O. Box 14155-6455, Tehran, Iran | ||
چکیده | ||
Previous studies have shown that certain urban elements and arsenic are significantly concentrated in the surface soils of Hamedan, the largest city in western Iran. This study was carried out to assess the non-cancer and cancer risks from exposure to these potentially harmful elements (As, Cd, Cr, Cu, Ni, Pb, and Zn) for Hamedan residence. In so doing, thirty-one urban and three background soil samples were analyzed by ICP-MS and the Risk Assessment Model established by the USEPA was applied to assess the health risk. It was found that the hazard index values for all the concerned elements are below 1, which indicates negligible to low non-carcinogenic risk for the exposed population. Nevertheless, some close to threshold values were recognized for As, Cr, and Pb implying that these elements have the potential to cause non-cancer risk for Hamedan citizens in case of long-term overexposure. The contribution of HQ-ingestion to total HI was the highest while the health effect associated with the inhalation exposure was trivial. Children were found to be more susceptible to potentially harmful elements than adults. The cancer risk calculation revealed that both children and adults are at increasing risk of developing cancer over a lifetime through ingestion, inhalation, and skin contact. All of the verified elements exceeded the tolerable level (1×10-6) of cancer risk however arsenic and chromium were found to be the most carcinogenic elements followed by Pb, Ni, and Cd. The carcinogenic risks were moderate for adults and high for children. This study indicates the necessity of designing effective strategies to reduce elemental pollution and to mitigate adverse human health effects of PHEs in Hamedan. | ||
کلیدواژهها | ||
Anthropogenic pollutants؛ Carcinogenic Risk؛ Non-Carcinogenic Risk؛ Toxic elements | ||
مراجع | ||
Abrahams, P. (2002). Soils: their implications to human health. Sci. Total Environ., 291(1-3): 1-32. Adimalla, N. (2020). Heavy metals pollution assessment and its associated human health risk evaluation of urban soils from Indian cities: a review. Environ Geochem Hlth., 42(1): 173-190. Albanese, S. and Breward, N. (2011). Sources of anthropogenic contaminants in the urban environment. (In: Johnson, Christopher C., (Ed.) Mapping the chemical environment of urban areas; pp. 116-127; Wiley. Alloway, B. J. (2013). Sources of heavy metals and metalloids in soils. (In Heavy metals in soils (pp. 11-50). Dordrecht: Springer) Antoniadis, V., Shaheen, S. M., Levizou, E., Shahid, M., Niazi, N. K., Vithanage, M., Ok, Y. S., Bolan, N. and Rinklebe, J. (2019). A critical prospective analysis of the potential toxicity of trace element regulation limits in soils worldwide: Are they protective concerning health risk assessment?-A review. Environ. Int., 127: 819-847. Argyraki, A. and Kelepertzis, E. (2014). Urban soil geochemistry in Athens, Greece: the importance of local geology in controlling the distribution of potentially harmful trace elements. Sci. Total Environ., 482: 366-377. Benhaddya, M. L., Boukhelkhal, A., Halis, Y. and Hadjel, M. (2016). Human health risks associated with metals from urban soil and road dust in an oilfield area of Southeastern Algeria. Arch. Environ. Contam. Toxicol., 70(3): 556-571. Biasioli, M., Grčman, H., Kralj, T., Madrid, F., Díaz-Barrientos, E. and Ajmone-Marsan, F. (2007). Potentially toxic elements contamination in urban soils. J. Environ. Qual., 36(1): 70-79. Cappelletti, N., Astoviza, M., Morrone, M. and Tatone, L. (2018). Urban geochemistry and potential human health risks in the Metropolitan Area of Buenos Aires: PAHs and PCBs in soil, street dust, and bulk deposition. Environ Geochem Hlth., 41(2); 699-713. Charlesworth, S., De Miguel, E. and Ordóñez, A. (2011). A review of the distribution of particulate trace elements in urban terrestrial environments and its application to considerations of risk. Environ Geochem Hlth., 33(2): 103-123. Cheng, H., Li, M., Zhao, C., Li, K., Peng, M., Qin, A. and Cheng, X. (2015). Overview of trace metals in the urban soil of 31 metropolises in China. J. Geochem. Explor., 139: 31-52. Cicchella, D., Zuzolo, D., Albanese, S., Fedele, L., Di Tota, I., Guagliardi, I., Thiombane, M., De Vivo, B. and Lima, A. (2020). Urban soil contamination in Salerno (Italy): Concentrations and patterns of major, minor, trace and ultra-trace elements in soils. J. Geochem. Explor., 213: 106519. Cohen, B. (2004). Urban growth in developing countries: a review of current trends and a caution regarding existing forecasts. World Dev., 32(1): 23-51. Duker, A. A., Carranza, E. and Hale, M. (2005). Arsenic geochemistry and health. Environ. Int., 31(5): 631-641. Eghbal, N., Nasrabadi, T., Karbassi, A. and Taghavi, L. (2019). Investigating the pattern of soil metallic pollution in urban areas (case study: a district in Tehran city). IJEST., 16(11): 6717-6726. Fazeli, G., Karbassi, A., Khoramnejadian, S. and Nasrabadi, T. (2019). Evaluation of urban soil pollution: a combined approach of toxic metals and polycyclic aromatic hydrocarbons (PAHs). Int. J. Environ. Res., 13(5): 801-811. Flem, B., Eggen, O. A., Torgersen, E., Kongsvik, M. K. and Ottesen, R. T. (2018). Urban geochemistry in Kristiansand, Norway. J. Geochem. Explor., 187: 21-33. Fryer, M., Collins, C. D., Ferrier, H., Colvile, R. N. and Nieuwenhuijsen, M. J. (2006). Human exposure modelling for chemical risk assessment: a review of current approaches and research and policy implications. Environ Sci Policy., 9(3): 261-274. Garcia-Sanchez, A. and Alvarez-Ayuso, E. (2003). Arsenic in soils and waters and its relation to geology and mining activities (Salamanca Province, Spain). J. Geochem. Explor., 80(1): 69-79. Giusti, L. (2011). Heavy metals in urban soils of Bristol (UK). Initial screening for contaminated land. J. Soils Sediments., 11(8): 1385-1398. Hamzeh, M. and Hasanzadeh, R. (2009). Study of soil pollution in the Kerman Urban areas with trace toxic elements, using GIS-based approach. J. Environ. Stud., 35(49): 41-52. Hiller, E., Filová, L., Jurkovič, Ľ., Mihaljevič, M., Lachká, L. and Rapant, S. (2020). Trace elements in two particle size fractions of urban soils collected from playgrounds in Bratislava (Slovakia). Environ Geochem Hlth., 42(11); 3925-3947. Hołtra, A. and Zamorska-Wojdyła, D. (2018). The input of trace elements from the motor transport into urban soils of Wrocław, Poland. Sci. Total Environ., 631: 1163-1174. Hosseini, N. S., Sobhanardakani, S., Cheraghi, M., Lorestani, B. and Merrikhpour, H. (2020). Heavy metal concentrations in roadside plants (Achillea wilhelmsii and Cardaria draba) and soils along some highways in Hamedan, west of Iran. Environ. Sci. Pollut. Res., 27(12): 13301-13314. Huang, J., Li, F., Zeng, G., Liu, W., Huang, X., Xiao, Z., Wu, H., Gu, Y., Li, X. and He, X. (2016). Integrating hierarchical bioavailability and population distribution into potential eco-risk assessment of heavy metals in road dust: A case study in Xiandao District, Changsha city, China. Sci. Total Environ., 541: 969-976. Jahandari, A. (2020). Pollution status and human health risk assessments of selected heavy metals in urban dust of 16 cities in Iran. Environ. Sci. Pollut. Res., 27(18): 23094-23107. Karim, Z. and Qureshi, B. A. (2014). Health risk assessment of heavy metals in urban soil of Karachi, Pakistan. Hum Ecol Risk Assess., 20(3): 658-667. Khodakarami, L.(2010). Evaluation of Agricultural Nonpoint Pollutant Resources, using GIS and RS. Environmental Science Department. Isfahan, Iran, Dissertation. Isfahan University of Technology (IUT). Khosravi, E., Houdaji, M. and Etemadifar, M. (2014). The Relationship of Concentrations of Lead and Zinc and Multiple Sclerosis in Isfahan Province, Iran. J Isfahan Med Sch., 32(275): 160-169 (In Persian). Kowalska, J. B., Mazurek, R., Gąsiorek, M. and Zaleski, T. (2018). Pollution indices as useful tools for the comprehensive evaluation of the degree of soil contamination–A review. Environ Geochem Hlth., 40(6): 2395-2420. Luo, X.-S., Ding, J., Xu, B., Wang, Y.-J., Li, H.-B. and Yu, S. (2012). Incorporating bioaccessibility into human health risk assessments of heavy metals in urban park soils. Sci. Total Environ., 424: 88-96. Martin, S. and Griswold, W. (2009). Human health effects of heavy metals. Environmen-tal science and technology briefs for citizens. Center for Hazardous Substance Research, Kansas State University 15. Modabberi, S., Tashakor, M., Soltani, N. S. and Hursthouse, A. S. (2018). Potentially toxic elements in urban soils: source apportionment and contamination assessment. Environ Monit Assess., 190(12): 715. Mohammadi, M. J., Yari, A. R., Saghazadeh, M., Sobhanardakani, S., Geravandi, S., Afkar, A., Salehi, S. Z., Valipour, A., Biglari, H. and Hosseini, S. A. (2018). A health risk assessment of heavy metals in people consuming Sohan in Qom, Iran. Toxin Rev., 37(4): 278-286. Montgomery, M. R. (2008). The urban transformation of the developing world. science 319(5864): 761-764. Morera-Gómez, Y., Alonso-Hernández, C. M., Armas-Camejo, A., Viera-Ribot, O., Morales, M. C., Alejo, D., Elustondo, D., Lasheras, E. and Santamaría, J. M. (2021). Pollution monitoring in two urban areas of Cuba by using Tillandsia recurvata (L.) L. and top soil samples: Spatial distribution and sources. Ecol. Indic., 126: 107667. Morera-Gómez, Y., Alonso-Hernández, C. M., Santamaría, J. M., Elustondo, D., Lasheras, E. and Widory, D. (2020). Levels, spatial distribution, risk assessment, and sources of environmental contamination vectored by road dust in Cienfuegos (Cuba) revealed by chemical and C and N stable isotope compositions. Environ. Sci. Pollut. Res., 27(2): 2184-2196. Nasrabadi, T. and Bidabadi, N. S. (2013). Evaluating the spatial distribution of quantitative risk and hazard level of arsenic exposure in groundwater, case study of Qorveh County, Kurdistan Iran. Iran J Environ Healt., 10(1): 1-8. Nasrabadi, T., Maedeh, P. A., Sirdari, Z., Bidabadi, N. S., Solgi, S. and Tajik, M. (2015). Analyzing the quantitative risk and hazard of different waterborne arsenic exposures: case study of Haraz River, Iran. Environ Earth Sci., 74(1): 521-532. Ngole-Jeme, V. M. and Fantke, P. (2017). Ecological and human health risks associated with abandoned gold mine tailings contaminated soil. PloS one 12(2): e0172517. Norra, S. (2009). The astysphere and urban geochemistry—a new approach to integrate urban systems into the geoscientific concept of spheres and a challenging concept of modern geochemistry supporting the sustainable development of planet earth. Environ. Sci. Pollut. Res., 16(5): 539-545. Othman, M. and Latif, M. T. (2020). Pollution characteristics, sources, and health risk assessments of urban road dust in Kuala Lumpur City. Environ. Sci. Pollut. Res., 1-19. Pan, L., Wang, Y., Ma, J., Hu, Y., Su, B., Fang, G., Wang, L. and Xiang, B. (2017). A review of heavy metal pollution levels and health risk assessment of urban soils in Chinese cities. Environ. Sci. Pollut. Res., 25(2): 1055-1069. Raj, D. and Maiti, S. K. (2020). Sources, bioaccumulation, health risks and remediation of potentially toxic metal (loid) s (As, Cd, Cr, Pb and Hg): an epitomised review. Environ Monit Assess., 192(2): 108. Rapant, S., Fajčíková, K., Khun, M. and Cvečková, V. (2011). Application of health risk assessment method for geological environment at national and regional scales. Environ Earth Sci., 64(2): 513-521. Rate, A. W. (2018). Multielement geochemistry identifies the spatial pattern of soil and sediment contamination in an urban parkland, Western Australia. S Sci. Total Environ., 627: 1106-1120. Robson, M. (2003). Methodologies for assessing exposures to metals: human host factors. Ecotox Environ Safe., 56(1): 104-109. Rodríguez-Seijo, A., Andrade, M. L. and Vega, F. A. (2017). Origin and spatial distribution of metals in urban soils. J. Soils Sediments., 17(5): 1514-1526. Sappa, G., Barbieri, M. and Andrei, F. (2020). Assessment of trace elements natural enrichment in topsoil by some Italian case studies. SN Applied Sciences 2(8): 1-19. Sobhanardakani, S. (2018a). Human health risk assessment of potentially toxic heavy metals in the atmospheric dust of city of Hamedan, west of Iran. Environ. Sci. Pollut. Res., 25(28): 28086-28093. Sobhanardakani, S. (2018b). Assessment of Pb and Ni contamination in the topsoil of ring roads' green spaces in the city of Hamadan. Pollution, 4(1): 43-51. Solgi, E., Roohi, N. and Kouroshi-Gholampour, M. (2016). A comparative study of metals in roadside soils and urban parks from Hamedan metropolis, Iran. Environmental Nanotechnology, Monitoring & Management 6: 169-175. United Nations. (2018). Revision of World Urbanization Prospects. United Nations: New York, NY, USA. USEPA. (2002). (United States Environment Protection Agency),OSWER 9355.4–24 December 2002. Supplemental Guidance for Developing Soil Screening Levels for Superfund Sites. Office of Emergency and Remedial Response, U.S. Environmental Protection Agency, Washington, DC 20460 Wei, B. and Yang, L. (2010). A review of heavy metal contaminations in urban soils, urban road dusts and agricultural soils from China. Microchem. J., 94(2): 99-107. Whitacre, D. M. (2008). Reviews of environmental contamination and toxicology: Springer. Wong, C. S., Li, X. and Thornton, I. (2006). Urban environmental geochemistry of trace metals. Environ Pollut., 142(1): 1-16. Woszczyk, M., Spychalski, W. and Boluspaeva, L. (2018). Trace metal (Cd, Cu, Pb, Zn) fractionation in urban-industrial soils of Ust-Kamenogorsk (Oskemen), Kazakhstan—implications for the assessment of environmental quality. Environ Monit Assess., 190(6): 362. Yang, F. and Massey, I. Y. (2019). Exposure routes and health effects of heavy metals on children. Biometals 32(4): 563-573. Yang, Z.-B., Yang, Y.-X., Shao, J.-R., Zhu, X.-M., Cheng, Z., Li, H.-H., Chen, L.-J., Yu, L., Guo, Z.-B., Shan, C.-Q., Lin, J.-Q. and Gu, Y.-G. (2017). Pollution characteristics and risk assessment of human exposure to oral bioaccessibility of heavy metals via urban street dusts from different functional areas in Chengdu, China. Sci. Total Environ., 586: 1076-1084. Yeganeh, M., Afyuni, M., Khoshgoftarmanesh, A.-H., Soffianian, A.-R. and Schulin, R. (2012). Health risks of metals in soil, water, and major food crops in Hamedan Province, Iran. Hum Ecol Risk Assess.,18(3): 547-568. Yesilonis, I., Pouyat, R. and Neerchal, N. (2008). Spatial distribution of metals in soils in Baltimore, Maryland: role of native parent material, proximity to major roads, housing age and screening guidelines. Environ Pollut., 156(3): 723-731. Zhang, G., Shao, L., Li, F., Yang, F., Wang, J. and Jin, Z. (2020). Bioaccessibility and health risk assessment of Pb and Cd in urban dust in Hangzhou, China. Environ. Sci. Pollut. Res.,1-12. | ||
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