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Accumulation of PAHs of the soils and assessment of their health risks at a village with plastic manufacturing in Taizhou, Zhejiang Province, Southeast China

  • Xinzhe Lu
  • Anqing Gu
  • Yanwu Zhang
  • Xianyao Chu
  • Xue-Feng HuEmail author
Soils, Sec 2 • Global Change, Environ Risk Assess, Sustainable Land Use • Research Article
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Abstract

Purpose

Accumulation of polycyclic aromatic hydrocarbons (PAHs) in soil had drawn increasing attention for their potential toxic effects on human health and ecological system. This work tried to probe into a possible link between the accumulation of PAHs in soil and a high incident of cancer at a plastic-manufacturing village in Taizhou, Zhejiang Province, Southeast China.

Materials and methods

Eight soil samples were collected nearby two plastic-processing plants at the village. The samples were air dried and stored at 4 °C for chemical analyses. Sixteen monomers of PAHs in the samples, listed as the precedently controlled pollutants by the US Environmental Protection Agency (USEPA), were analyzed using the gas chromatography–mass spectrometry. A model of incremental lifetime cancer risks (ILCRs) specified by USEPA were used to assess their health risks.

Results and discussion

The total concentrations of precedent-controlled 16 PAHs in the soils are in a range of 2.3–366.4 ng g−1, with an average of 129.03 ng g−1. Those of seven carcinogenic PAHs are in a range of 0–123.9 ng g−1, with 58.46 ng g−1 on average. The concentrations of PAHs in the soils were much higher nearby the plastic-processing plants. The ILCRs of adults and children who are exposed to PAHs in the soil through oral intake and skin touch are in a range of 10−8 ~ 10−5.

Conclusions

The soils nearby the plastic-processing plants have higher contents of PAHs. The PAHs are dominated by middle- and higher-ring monomers, suggesting the origin of high-temperature combustion. The ratios of specific monomers also indicated that PAHs in the soils mostly originate from plastic manufacturing. A cancer risk of adults from PAH exposure in the soil through oral intake and skin touch attains a potential level. That of children can never be ignored. It proves that a high incidence of cancer in the study areas is correlated with the industrial emissions of PAHs from the plastic plants.

Keywords

Health risks PAHs Plastic processing Soil 

Notes

Funding information

The research was supported by the financial fund from Zhejiang Province in China (No. 2016009-07 and No.2019007) and the National Natural Science Foundation of China (No. 41877005) and the research grants from the Science and Technology Commission of Shanghai Municipality (No. 17 DZ1202300) and the Agriculture Research System of Shanghai, China (Grant No. 201909).

References

  1. Britt PF, BuchananIII AC, Kidder MK, Owens CV Jr (2003) Influence of steroid structure on the pyrolytic formation of polycyclic aromatic hydrocarbons. J Anal Appl Pyrolysis 66:71–95CrossRefGoogle Scholar
  2. Bogan BW, Sullivan WR (2003) Physicochemical soil parameters affecting sequestration and mycobacterial biodegradation of polycyclic aromatic hydrocarbons in soil. Chemosphere 52:1717–1726CrossRefGoogle Scholar
  3. Cai QY, Mo CH, Wu QT, Katsoyiannis A, Zeng QY (2008) The status of soil contamination by semivolatile organic chemicals (SVOCs) in China: a review. Sci Total Environ 389:209–224CrossRefGoogle Scholar
  4. Chen JC, Huang JS, Chen CM, Guo JS (2008) Emission characteristics of PAHs, benzene and phenol group hydrocarbons in O2/RFG waste incineration processes. Fuel 87:2787–2797CrossRefGoogle Scholar
  5. Collins JF, Brown JP, Alexeeff GV, Salmon AG (1998) Potency equivalency factors for some polycyclic aromatic hydrocarbons and polycyclic aromatic hydrocarbon derivatives. Regul Toxicol Pharmacol 28:45–54CrossRefGoogle Scholar
  6. Dai J, Li S, Zhang Y, Wang R, Yu Y (2008) Distributions, sources and risk assessment of polycyclic aromatic hydrocarbons (PAHs) in topsoil at Jinan city, China. Environ Monit Assess 147:317–326CrossRefGoogle Scholar
  7. Dauner ALL, Dias TH, Ishii FK, Libardoni BG, Parizzi RA, Martins CC (2018) Ecological risk assessment of sedimentary hydrocarbons in a subtropical estuary as tools to select priority areas for environmental management. J Environ Manag 223:417–425CrossRefGoogle Scholar
  8. Doabi SA, Karami M, Afyuni M, Yeganeh M (2018) Pollution and health risk assessment of heavy metals in agricultural soil, atmospheric dust and major food crops in Kermanshah province, Iran. Ecotox Environ Safe 163:153–164CrossRefGoogle Scholar
  9. Dong TTT, Lee BK (2009) Characteristics, toxicity, and source apportionment of polycyclic aromatic hydrocarbons (PAHs) in road dust of Ulsan, Korea. Chemosphere 74:1245–1253CrossRefGoogle Scholar
  10. Fayeulle A, Veignie E, Schroll R, Munch JC, Rafin C (2019) PAH biodegradation by telluric saprotrophic fungi isolated from aged PAH-contaminated soils in mineral medium and historically contaminated soil microcosms. J Soils Sediments 19:3056–3067CrossRefGoogle Scholar
  11. Fechner D, Seifert B (2003) Determination of polycyclic aromatic hydrocarbons in dust deposits by high-performance liquid chromatography using multi-wavelength detection: part I. qualitative results. J Anal Appl Pyrolysis 70:73–85CrossRefGoogle Scholar
  12. Gdara I, Zrafi I, Balducci C, Cecinato A, Ghrabi A (2018) Seasonal occurrence, source evaluation and ecological risk assessment of polycyclic aromatic hydrocarbons in industrial and agricultural effluents discharged in Wadi EI Bey (Tunisia). Environ Geochem Health 20:1–19Google Scholar
  13. Horii Y, Ok G, Ohura T, Kannan K (2008) Occurrence and profiles of chlorinated and brominated polycyclic aromatic hydrocarbons in waste incinerators. Environ Sci Technol 42:1904–1909CrossRefGoogle Scholar
  14. Huang HF, Xing XL, Zhang ZZ, Qi SH, Yang D, Yuen DA, Sandy EH, Zhou AG, Li XQ (2016) Polycyclic aromatic hydrocarbons (PAHs) in multimedia environment of Heshan coal district, Guangxi: distribution, source diagnosis and health risk assessment. Environ Geochem Health 38:1169–1181CrossRefGoogle Scholar
  15. Hsu WT, Liu MC, Hung PC, Chang SH, Chang MB (2016) PAH emissions from coal combustion and waste incineration. J Hazard Mater 318:32–40CrossRefGoogle Scholar
  16. Katsoyiannis A, Sweetman AJ, Jones KC (2011) PAH molecular diagnostic ratios applied to atmospheric sources: a critical evaluation using two decades of source inventory and air concentration data from the UK. Environ Sci Technol 45:8897–8906CrossRefGoogle Scholar
  17. Li T, Feng Q, Qian B, Zhou L, Gao B (2013) Chemical characteristics of coal mine drainage and its impact on the environment in Shandong province. China J Chem Pharm Res 5:146–151Google Scholar
  18. Li W, Shen G, Yuan C, Wang C, Shen H, Jiang H, Zhang YY, Chen YC, Su S, Lin N, Tao S (2015a) The gas/particle partitioning of nitro- and oxy-polycyclic aromatic hydrocarbons in the atmosphere of northern China. Atmos Res 172:18–22Google Scholar
  19. Li Y, Zhang L, Hou W, Li YL, Li X (2015b) Research on content, distribution and health risk assessment of PAHs in surface dust in Shenyang City. Nat Environ Pollut Technol 14:721–726Google Scholar
  20. Liu H, Yu X, Liu Z, Sun Y (2018) Occurrence, characteristics and sources of polycyclic aromatic hydrocarbons in arable soils of Beijing, China. Ecotox Environ Safe 159:120–126CrossRefGoogle Scholar
  21. Lu XZ, Luo F, Gu AQ, Chu XY, Younas H, Hu XF (2018) Sources and risk assessment of toxic elements in the agricultural soil of Tiantai County of Zhejiang province, China. Hum Ecol Risk Assess.  https://doi.org/10.1080/10807039.2018.1525680
  22. Mao XX, Yu ZS, Ding ZY, Huang T, Ma J, Zhang G, Li J, Gao H (2016) Sources and potential health risk of gas phase PAHs in Hexi Corridor, Northwest China. Environ Sci Pollut Res 23:2603–2612CrossRefGoogle Scholar
  23. Masto RE, Sarkar E, George J, Jyoti K, Dutta P, Ram LC (2015) PAHs and potentially toxic elements in the fly ash and bed ash of biomass fired power plants. Fuel Process Technol 132:139–152CrossRefGoogle Scholar
  24. Munoz M, Heeb NV, Haag R, Honegger P, Zeyer K, Mohn J (2016) Bioethanol blending reduces nanoparticle, PAH, and alkyl- and nitro-PAH emissions and the genotoxic potential of exhaust from a gasoline direct injection flex-fuel vehicle. Environ Sci Technol 50:11853–11861CrossRefGoogle Scholar
  25. Mohammed FK, Beckles DM, Opadeyi J (2018) Characterization, source apportionment, and human health risk assessment of polycyclic aromatic hydrocarbons (PAHs) in road dust of a small island state in the Caribbean. Hum Ecol Risk Assess 24:1–20CrossRefGoogle Scholar
  26. Nadal M, Schuhmacher M, Domingo JL (2004) Levels of PAHs in soil and vegetation samples from Tarragona County, Spain. Environ Pollut 132:0–11CrossRefGoogle Scholar
  27. Oliva AL, La Colla NS, Arias AH, Blasina GE, Lopez CA, Marcovecchio JE (2017) Distribution and human health risk assessment of PAHs in four fish species from a SW Atlantic estuary. Environ Sci Pollut Res 24:1–12CrossRefGoogle Scholar
  28. Peng C, Chen WP, Liao XL, Wang ME, Ouyang ZY, Jiao WT, Bai Y (2011) Polycyclic aromatic hydrocarbons in urban soils of Beijing: status, sources, distribution and potential risk. Environ Pollut 159:802–808CrossRefGoogle Scholar
  29. Peters CA, And CDK, Brown DG (1999) Long-term composition dynamics of PAH-containing NAPLs and implications for risk assessment. Environ Sci Technol 33:4499–4507CrossRefGoogle Scholar
  30. Ping LF, Luo YM, Zhang HB, Li QB, Wu LH (2007) Distribution of polycyclic aromatic hydrocarbons in thirty typical soil profiles in the Yangtze River Delta region, East China. Environ Pollut 147:358–365CrossRefGoogle Scholar
  31. Qu CS, Li B, Wu HS, Wang S, Giesy JP (2015) Multi-pathway assessment of human health risk posed by polycyclic aromatic hydrocarbons. Environ Geochem Health 37:587–601CrossRefGoogle Scholar
  32. Rajasekhar B, Nambi IM, Govindarajan SK (2018) Human health risk assessment of ground water contaminated with petroleum PAHs using Monte Carlo simulations: a case study of an Indian metropolitan city. J Environ Manag 205:183–191CrossRefGoogle Scholar
  33. Reinecke AJ, Van Wyk M, Reinecke SA (2016) The influence of soil characteristics on the toxicity of oil refinery waste for the springtail Folsomia Candida (Collembola). Environ Contam Tox 96:804–809CrossRefGoogle Scholar
  34. Rorat A, Wloka D, Grobelak A, Grosser A, Sosnecka A, Milczarek M, Jelonek P, Vandenbulcke F, Kacprzak M (2017) Vermiremediation of polycyclic aromatic hydrocarbons and heavy metals in sewage sludge composting process. J Environ Manag 187:347–353CrossRefGoogle Scholar
  35. Sarenbo S (2009) Wood ash dilemma-reduced quality due to poor combustion performance. Biomass Bioenergy 33:1212–1220CrossRefGoogle Scholar
  36. Shakeri A, Madadi M, Mehrabi B (2016) Health risk assessment and source apportionment of PAHs in industrial and bitumen contaminated soils of Kermanshah province, NW Iran. Toxicol Environ Heal Sci 8:201–212CrossRefGoogle Scholar
  37. Shu WB, Zhao YB, Ni HG, Zeng H (2018) Size-dependent emission characteristics of airborne parent and halogenated PAHs from municipal solid waste incinerators in Shenzhen, China. Chemosphere 192:250–257CrossRefGoogle Scholar
  38. Singh DP, Gadi R, Mandal TK, Saud T, Saxena M, Sharma SK (2013) Emissions estimates of PAH from biomass fuels used in rural sector of indo-Gangetic plains of India. Atmos Environ 68:120–126CrossRefGoogle Scholar
  39. Suman S, Sinha A, Tarafdar A (2016) Polycyclic aromatic hydrocarbons (PAHs) concentration levels, pattern, source identification and soil toxicity assessment in urban traffic soil of Dhanbad, India. Sci Total Environ 545-546:353–360CrossRefGoogle Scholar
  40. Srogi K (2007) Monitoring of environmental exposure to polycyclic aromatic hydrocarbons: a review. Environ Chem Lett 5:169–195CrossRefGoogle Scholar
  41. Tang X, Shen C, Shi D, Cheema SA, Khan MI, Zhang C (2010) Heavy metal and persistent organic compound contamination in soil from Wenling: an emerging e-waste recycling city in Taizhou area, China. J Hazard Mater 173:653–660CrossRefGoogle Scholar
  42. USDOE (2011) The risk assessment information system (RAIS). U.S. Department of Energy’s Oak Ridge Operations Office (ORO). United States Department of Energy, WashingtonGoogle Scholar
  43. USEPA (1993) Reference dose (RfD): description and use in health risk assessments. Background document 1A. Integrated risk information system (IRIS). US. Environmental Protection Agency, WashingtonGoogle Scholar
  44. USEPA (1991) Risk assessment guidance for superfund human health evaluation manual (part B, development of risk-based preliminary remediation goals) vol 1: EPA/540/R-92/003 Publication 9285.7–01BGoogle Scholar
  45. USEPA (2002) Supplemental guidance for developing soil screening levels for superfund sites. OSWER 9355.4–24. US Environmental Protection Agency, WashingtonGoogle Scholar
  46. Wei GE, Cheng QQ, Chai C, Zeng LS, Wu J, Chen QH, Zhu XW, Ma D (2017) Pollution characteristics and source analysis of polycyclic aromatic hydrocarbons in agricultural soils from Shandong. Environ Sci 4:1587–1510 (in Chinese) Google Scholar
  47. Wu DH, Liu HX, Liu ML (2018) Pollution characteristics and health risk assessment of polycyclic aromatic hydrocarbons in soil from a typic peri-urban area. Environ Chem 37:1565–1574 (in Chinese)CrossRefGoogle Scholar
  48. Xia H, Gomez-Eyles JL, Ghosh U (2016) Effect of polycyclic aromatic hydrocarbon source materials and soil components on partitioning and dermal uptake. Environ Sci Technol 50:3444–3452CrossRefGoogle Scholar
  49. Xing W, Luo Y, Wu L (2016) Spatial distribution of PAHs in a contaminated valley in Southeast China. Environ Geochem Health 28:89–96CrossRefGoogle Scholar
  50. Yunker MB, Backus SM, Graf Pannatier G, Jeffries DS, Macdonald RW (2002) Sources and significance of alkane and PAH hydrocarbons in Canadian arctic rivers. Estuar Coast Shelf Sci 55:1–31CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  1. 1.Department of Environmental Science and Engineering, School of Environmental and Chemical EngineeringShanghai UniversityShanghaiChina
  2. 2.Zhejiang Institute of Geological SurveyHangzhouChina

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