Abstract
Polycyclic aromatic hydrocarbons (PAHs), organochlorine pesticides (OCPs) and phenolic compounds (PCs) are persistent organic compounds. Contamination of these potentially toxic organic pollutants in soils and sediments is most studied environmental compartments. In recent past, studies were carried out on PAHs, OCPs and PCs in various soils and sediments in India. But, this is the first study on these pollutants in soils and sediments from an urbanized river flood plain area in Delhi, India. During 2018, a total of fifty-four samples including twenty-seven each of soil and sediment were collected and analyzed for thirteen priority PAHs, four OCPs and six PCs. The detected concentration of ∑PAHs, ∑OCPs and ∑PCs in soils ranged between 473 and 1132, 13 and 41, and 639 and 2112 µg/kg, respectively, while their concentrations in sediments ranged between 1685 and 4010, 4.2 and 47, and 553 and 20,983 µg/kg, respectively. PAHs with 4-aromatic rings were the dominant compounds, accounting for 51 and 76% of total PAHs in soils and sediments, respectively. The contribution of seven carcinogen PAHs (7CPAHs) in soils and sediments accounted for 43% and 61%, respectively, to ∑PAHs. Among OCPs, p, p’-DDT was the dominant compound in soils, while α-HCH was found to be dominated in sediments. The concentrations of ∑CPs (chlorophenols) were dominated over ∑NPs (nitrophenols) in both the matrices. Various diagnostic tools were applied for the identification of their possible sources in soil and sediments. The observed concentrations of PAHs, OCPs and PCs were more or less comparable with the recently reports from various locations around the world including India. Soil quality guidelines and consensus-based sediment quality guidelines were applied for the assessment of ecotoxicological health effect.
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References
Aleksandra, U.-J., Smreczak, B., & Agnieszka K—P. . (2019). Soil organic matter composition as a factor affecting the accumulation of polycyclic aromatic hydrocarbons. Journal of Soils and Sediments, 19, 1890–1900.
Aislabie, J. M., Richards, N. K., & Boul, H. L. (1997). Microbial degradation of DDT and its residues-a review. New Zealand J Agricultural Research, 40, 269–282.
ATSDR (Agency for Toxic Substances and Disease Registry). 1995. Toxicological profile for polycyclic aromatic hydrocarbons (PAHs). US Department of Health and Human Services, Public Health Service. Atlanta, GA. Accessed 10.01.2020. http://www.atdsr.cdc.gov/toxpro.les/phs69.
ATSDR. 2005. Toxicological profile for hexachlorocyclohexanes. Accessed 20.01.2020. http://www.atsdr.cdc.gov/toxprofiles/index.asp.
ATSDR. 2008. Toxicological profile for DDT, DDE, and DDD. Accessed 20.01.2020. http://www.atsdr.cdc.gov/toxprofiles/index.asp.
Becker, B., Halshall, C. J., Tych, W., Kallenborn, R., Schiabch, M., & Mano, S. (2009). Changing sources and environmental factors reduce the rates of decline of organochlorine pesticides in the Arctic atmosphere. Atmospheric Chemistry and Physics Discussion, 9, 515–540.
Buckman, M.F. 2008. NOAA screening quick reference tables (SQuiRTs). NOAA OR&R REPORT 08–1, Seattle Washington, Office of the Response and Restoration Division, National Oceanography and Atmospheric Administration, 34 pages.
CCME. 2010. Canadian soil quality guidelines for the protection of environmental and human health: Carcinogenic and other PAHs. In: Canadian environmental quality guidelines, 1999, 200 Winnipeg, Canada, http://www.ccme.ca.
Chakraborty, P., Khuman, S. N., Selvaraj, S., Sampath, S., Devi, N. L., Bang, J. J., & Katsoyiannis, A. (2016). Polychlorinated biphenyls and organochlorine pesticides in River Brahmaputra from the outer Himalayan Range and River Hooghly emptying into the Bay of Bengal: Occurrence, sources and ecotoxicological risk assessment. Environmental Pollution, 219, 998–1006.
Debadatta, D., & Rajdeep, K. (2012). Biodegradation of phenols by various indigenous microorganisms. Journal of Environmental Research Division, 7, 1–7.
DERC (Delhi Electricity Regulatory Commission). 2017. Annual Report 2016–2017. Accessed on 30.01.2020 at http://www.derc.gov.in/
DES (Directorate of Economics and Statistics). 2016. Statistical Abstract of Delhi, 2016. Government of National Capital Territory of Delhi, Delhi, India. Accessed 30.01.2020 at http://des.delhigovt.nic.in/wps/wcm/connect/DOIT_DES/des/home/.
Dickhut, R. M., Canuel, E. A., Gustafson, K. E., Liu, K., Arzayus, K. M., Walker, S. E., et al. (2000). Automotive sources of carcinogenic polycyclic aromatic hydrocarbons associated with particulate matter in the Chesapeake Bay Region. Environmental Science Technology, 34, 4635–4640.
EC (European Community). 2001. The list of priority substances in the field of water policy and amending directive, Council directive 2455/2001/ECC. Official Journal L331, 1–5.
Goswami, P., Ohura, T., Guruge, K. S., Yoshioka, M., Yamanaka, N., Akiba, M., & Munuswamy, N. (2016). Spatio-temporal distribution, source, and genotoxic potential of polycyclic aromatic hydrocarbons in estuarine and riverine sediments from southern India. Ecotoxicol Environmental Safety, 130, 113–123.
Ghosh SP & Maiti SK. 2019. Evaluation of PAHs concentration and cancer risk assessment on human health in a roadside soil: A case study. Human and Ecol Risk Assess: An International Journal. DOI: https://doi.org/10.1080/10807039.2018.1551052
Hafner, W. D., Carlson, D. L., & Hites, R. A. (2005). Influence of local human population on atmospheric polycyclic aromatic hydrocarbon concentrations. Environmental Science & Technology, 39, 7374–7379.
IARC (International Agency for Research on Cancer). 2010. IARC Monographs on the evaluation of carcinogenic risks to humans. Vol. 92, Some Non-heterocyclic polycyclic aromatic hydrocarbons and some related exposures. Lyone, France, https://monographs.iarc.fr/monographs-available/ Accessed 10.01.2020
Kata, M., Rao, S. R., & Mohan, K. R. (2015). Spatial distribution, ecological risk evaluation and potential sources of organochlorine pesticides from soils in India. Environmental Earth Sciences, 74, 4031–4038.
Khalili, N. R., Scheff, P. A., & Holsen, T. M. (1995). PAH source fingerprints for coke ovens, diesel and gasoline engines, highway tunnels, and wood combustion emissions. Atmospheric Environmental, 29, 533–542.
Khaiwal, R., Ranjeet Sokhi, R., & Grieken, R. V. (2008). Atmospheric polycyclic aromatic hydrocarbons: Source attribution, emission factors and regulation. Atmospheric Environment, 42(13), 2895–2921.
Kumar, B., Verma, V. K., Mishra, M., Sanjay, K. S., Sharma, C. S., & Akolkar, A. B. (2014a). Persistent organic pollutants in residential soils of North India and assessment of human health hazard and risks. Toxicol Environmental Chemistry, 96(2), 255–272.
Kumar, B., Verma, V. K., Kumar, S., & Sharma, C. S. (2014b). Polycyclic aromatic hydrocarbons in residential soils from an Indian city near power plants area and assessment of health risk for human population. Polycyclic Aromatic Compounds, 34(3), 191–213.
Kumar, B., Tyagi, J., Verma, V. K., Sharma, C. S., & Akolkar, A. B. (2014c). Distribution of eleven priority phenolic compounds in soils from mixed landuse and assessment of health hazard for human population. Advances in Applied Science Research, 5(2), 125–132.
Kumar, B., Verma, V. K., Sharma, C. S., & Akolkar, A. B. (2014d). Quick and easy method for determination of priority phenolic compounds in water and wastewater. Journal of Xenobiotics, 4(1), 46–52.
Kumar, B., Verma, V. K., Sharma, C. S., & Akolkar, A. B. (2015a). Priority Polycyclic Aromatic Hydrocarbons (PAHs): Distribution, Possible Sources and Toxicity Equivalency in Urban Drains. Polycyclic Aromatic Compounds, 36(4), 342–363.
Kumar, B., Verma, V. K., Tyagi, J., Sharma, C. S., & Akolkar, A. B. (2015b). Health Risk Due to Sixteen PAHs in Residential Street Soils from Industrial Region, Ghaziabad, Uttar Pradesh, India. Journal of Environment Protection and Sustainable Development, 1(2), 101–106.
Kumar, B., Verma, V. K., Sharma, C. S., & Akolkar, A. B. (2015c). Estimation of toxicity equivalency and probabilistic health risk on lifetime daily intake of polycyclic aromatic hydrocarbons from urban residential soils. Human and Ecol Risk Assess: An International Journal, 21(2), 434–444.
Kumar, B., Verma, V. K., Mishra, M., Tyagi, J., Sharma, C. S., & Akolkar, A. B. (2016). Quantification of nitrophenols, chlorophenols and hexachlorocyclohexanes in agricultural soils in the vicinity of industrial area for the assessment of human health hazard and risk. Human Ecol Risk Assess: An Int J, 22(1), 39–49.
Kumar, B., Verma, V. K., Rai, P., Kumar, S., & Sharma, C. S. (2017). Distribution and ecotoxicological risk assessment of priority phenols in river bank sediments. International Journal of Geology Earth & Environment Sciences, 7(2), 63–69.
Kumar, B., Mishra, M., Verma, V. K., Rai, P., & Kumar, S. (2018). Organochlorines in urban soils from Central India: probabilistic health hazard and risk implications to human population. Environmental Geochemistry and Health, 40, 2465–2480.
Khuman, S. N., & Chakraborty, P. (2019). Air-water exchange of pesticidal persistent organic pollutants in the lower stretch of the transboundary river Ganga, India. Chemosphere, 233, 966–974.
Khuman, S. N., Chakraborty, P., Cincinelli, A., Snow, D., & Kumar, B. (2018). Polycyclic aromatic hydrocarbons in surface waters and riverine sediments of the Hooghly and Brahmaputra Rivers in the Eastern and Northeastern India. Science and Total Environment, 636, 751–760.
Laine, M., & Jorgensen, K. (1996). Straw compost and bioremediated soil as inocula for the bioremedation of chlorophenols –contaminated soil. Applied Environment and Microbiology, 54, 1507.
Li, G., Sun, G. X., Ren, Y., Lu, X. S., & Zhu, Y. G. (2018). Urban soil and human health: a review. European Journal of Soil Science. https://doi.org/10.1111/ejss.12518.
Marr, L. C., Kirchstetter, T. W., & Harley, R. A. (1999). Characterization of polycyclic aromatic hydrocarbons in motor vehicle fuels and exhaust emissions. Environmental Science Technology, 33, 3091–3099.
Marianna, C. (2004). Sources and transformations of chlorophenols in the natural environment. Science of the Total Environment, 322, 21–39.
Malaiyandi, M., & Shah, S. (1980). Evidence of photoisomerization of hexachlorocyclohexane isomers in the ecosphere. Journal of Environmental Science Health, 887–910(A19), 887–910.
McLellan, I., Carvalho, M., PereiraC, S., Hursthouse, A., Morrison, C., Tatner, P., et al. (2007). The environmental behaviour of polychlorinated phenols and its relevance to cork forest ecosystems: a review. Journal Environmental Monitor, 9, 1055–1063.
Mitra, S., Corsolini, S., Pozo, K., Audy, O., Sarkar, S. K., & Biswas, J. K. (2019). Characterization, source identification and risk associated with polyaromatic and chlorinated organic contaminants (PAHs, PCBs, PCBzs and OCPs) in the surface sediments of Hooghly estuary, India. Chemosphere, 221, 154–165.
Maliszewska-Kordybach, B. (1996). Polycyclic aromatic hydrocarbons in agricultural soils in Poland: preliminary proposals for criteria to evaluate the level of soil contamination. Applied Geochemical, 11, 121–127.
O’Driscoll, K., Mayer, B., Su, J., & Mathis, M. (2014). The effects of global climate change on the cycling and processes of persistent organic pollutants (POPs) in the North Sea. Ocean Science, 10, 397–409.
Olujimi, O. O., Fatoki, O. S., Odendaal, J. P., & Okonkwo, J. O. (2010). Endocrine disrupting chemicals (phenol and phthalates) in the South African environment: A need for more monitoring. Water SA, 36(5), 671–682.
Patnaik, P., & Khoury, J. (2004). Reaction of phenol with nitrite ion: pathways of formation of nitrophenols in environmental waters. Water Research, 38, 206.
Persson, Y., Lundstedt, S., Berg, L., & Tysklind, M. (2007). Levels of chlorinated compounds (CPs, PCPPs, PCDEs, PCDFs and PCDDs) in soils at contaminated sawmill sites in Sweden. Chemosphere, 66, 234–242.
Pozo, K., Sarkar, S. K., Estellano, V. H., Mitra, S., Audi, O., Kukucka, P., et al. (2017). Passive air sampling of persistent organic pollutants (POPs) and emerging compounds in Kolkata megacity and rural mangrove wetland Sundarban in India: An approach to regional monitoring. Chemosphere, 168, 1430–1438.
PPQS (Plant Protection Quarantine & Storage). (2019). Directorate of Plant Protection Quarantine & Storage. Central Insecticides Board & Registration Committee. Lists of pesticides banned, refused registration and restricted. http://ppqs.gov.in/ Accessed 30.01.2020.
Ray, S., Khillare, P. S., & Kim, K. H. (2013). Profiles, carcinogenic potencies, sources and association of black carbon and polycyclic aromatic hydrocarbons in size-fractionated urban and forest soils of Delhi, India. International Journal of Environmental Engineering and Management, 4(6), 581–584.
Santana, C. M., Ferrera, Z. S., Padron, M. E. T., & Rodrigues, J. J. S. (2009). Methodologies for the extraction of phenolic compounds from environmental samples: new approaches. Molecules, 14, 298–320.
Simcik, M. F., Eisenreich, S. J., & Lioy, P. J. (1999). Source apportionment and source/sink relationship of PAHs in the coastal atmosphere of Chicago and Lake Michigan. Atmospheric Environment, 33, 5071–5079.
Singh, D. P., Gadi, R., & Mandal, T. K. (2012). Levels, sources, and toxic potential of polycyclic aromatic hydrocarbons in urban soil of Delhi, India. Human Ecology Risk Assess: An International Journal, 18(2), 393–411.
Sulabh, 2019. National status of waste water generation & treatment. Sulabh Bhawan, New Delhi-110045. Accessed 03.04.2020, http://www.sulabhenvis.nic.in/Database/STST_wastewater_2090.aspx.
Tavares, T. M., Beretta, M., & Costa, M. C. (1999). Ratio of DDT/DDE in the all Saints Bay, Brazil, and its use in environmental management. Chemosphere, 38, 1445–1452.
Tsai, P. J., Shih, T. S., Chen, H. L., et al. (2004). Assessing and predicting the exposures of polycyclic aromatic hydrocarbons (PAHs) and their carcinogenic potencies from vehicle engine exhausts to highway toll station workers. Atmospheric Environmental, 38, 333–343.
USEPA (United States Environmental Protection Agency). 2015. Appendix A to 40 CFR, Part 423–126 Priority Pollutants. Accessed 30.01.2020, https://www.gpo.gov/fdsys/pkg/CFR-2018-title40-vol31/pdf/CFR-2018-title40-vol31-part423-appA.pdf.
UNEP (United Nations Environmental Programme). 2011. National implementation plans Stockholm Convention on persistent organic pollutants (POPs). Accessed 21 March 2019, http://chm.pops.int/Implementation/NIPs/NIPTransmission/tabid/253/Default.aspx.
UNEP (United Nations Environmental Programme). 2017. Revised Texts and Annexes. http://www.pops.int/Home/tabid/2121/Default.aspx. Accessed 15.02.2020
Wang, X., Wang, D., Qin, X., & Xu, X. (2008). Residues of organochlorine pesticides in surface soils from college school yards in Beijing, China. Journal Environmental Science, 20, 1090–1096.
Wang, Z., Ma, X., Na, G., Lin, Z., Ding, Q., & Yao, Z. (2009). Correlations between physicochemical properties of PAHs and their distribution in soil, moss and reindeer dung at Ny-Ålesund of the Arctic. Environmental Pollution, 157, 3132–3136.
Wang, C., Wu, S., Zhou, S., Shi, Y., & Song, J. (2017). Characteristics and source identification of polycyclic aromatic hydrocarbons (PAHs) in urban soils: A review. Pedosphere, 27(1), 17–26.
WDNR (Wisconsin Department of Natural Resources). 2003. Consensus-based sediment quality guidelines (CB-SQGs) recommendations for use and application interim guidance. Accessed 15.01.2020, https://dnr.wi.gov/files/PDF/pubs/rr/RR088.pdf.
WHO (World Health Organization). (1989). Environmental health criteria 93. Chlorophenols other than pentachlorophenol. Geneva.
Wilcke, W. (2000). Polycyclic aromatic hydrocarbons (PAHs) in soil–a review. Journal of Plant Nutrition Soil Science, 163, 229–243.
Yahaya, A., Okoh, O. O., Agunbiade, F. O., & Okoh, A. L. (2019). Occurrence of phenolic derivatives in Buffalo River of eastern Cape South Africa: exposure risk evaluation. Ecototocol Environment and Safety, 171, 887–893.
Yunker, M. B., Macdonald, R. W., Vingarzan, R., Mitchell, H. R., Goyette, D., & Sylvestre, S. (2002). PAHs in the Fraser River basin: a critical appraisal of PAH ratios as indicators of PAH source and composition. Organic Geochemistry, 33, 489–515.
Zhou, M., Zhang, J., & Sun, C. (2017). Occurrence ecological and human health risk and seasonal variations of phenolic compounds in surface water and sediments of a potential polluted river basin in China. International Journal Environmental Research Public Health, 14(10), 1–14.
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The authors are grateful to competent authorities of Central Pollution Control Board for providing the necessary facilities to conduct study. Piyush, VK and AT are also thankful to CPCB for permission to carried out study for postgraduate dissertations. The views expressed in this paper are those of authors and do not necessarily reflect the organization’s.
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Kumar, B., Verma, V.K., Mishra, M. et al. Assessment of persistent organic pollutants in soil and sediments from an urbanized flood plain area. Environ Geochem Health 43, 3375–3392 (2021). https://doi.org/10.1007/s10653-021-00839-9
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DOI: https://doi.org/10.1007/s10653-021-00839-9