Abstract
Irrigation of crops by arsenic contaminated groundwater leads to buildup of arsenic in soil and transfer to humans via bioaccumulation in crops. However, many factors, like available concentration of arsenic in soil, accumulation in edible portion of the crops and intake rate determine the final risk. The present study has attempted to characterize all these related factors. Groundwater arsenic content varied between 23 ± 5.33 to 176 ± 49 μg L−1. Total arsenic in agricultural soil ranged from 3.92 to 7.05 mg kg−1 dry weight. Sequential extraction of soil revealed the major fraction in majority of the samples to be residual, with available fraction varying within 0.06 to 1.58 mg kg−1, exhibiting positive correlation between total and available arsenic content in soil. Positive correlation was observed between As-Fe (R2 = 0.55) and As-clay content (R2 = 0.42). Accumulation in 25 plant species ranged from 0.07 to 0.58 mg kg−1 dry weight. The Bioconcentration Factor was highest in pigeon pea and significantly high in paddy. Analysis of the different parts of the plant indicated higher accumulation in potato tuber and radish, in which the below ground parts are edible. Apart from this, in the above ground edible parts, accumulation was high in wheat, maize, spinach, coriander, brinjal and cucumber. Further, the Health Risk Index, calculated on the basis of daily intake, indicated maximum risk with consumption of food according to the following order: wheat (2.18), paddy (1.13), potato (0.47), pumpkin (0.39) and spinach (0.24). Observations thus suggest high risk of food items which are generally consumed daily.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alam MG, Snow ET, Tanaka A (2003) Arsenic and heavy metal contamination of vegetables grown in Samta village. Bangladesh. Sci Total Environ 308:83–96
Alam MO, Shaikh WA, Chakraborty S, Avishek K, Bhattacharya T (2016) Groundwater arsenic contamination and potential health risk assessment of Gangetic Plains of Jharkhand, India. Expo Health 8:125–142. doi:10.1007/s12403–015–0188-0
Bhattacharjee S, Chakravarty S, Maity S, Dureja V, Gupta KK (2005) Metal contents in the groundwater of Sahebgunj district, Jharkhand, India, with special reference to arsenic. Chemosphere 58:1203–1217
Bhattacharya P, Samal AC, Majumdar J, Santra SC (2010) Accumulation of arsenic and its distribution in rice plant (Oryza sativa L.) in gangetic West Bengal, India. Paddy water. Environment 8:63–70
BIS (2012) Indian Standard: Drinking water – Specification (second revision) IS 10500: 2012. Bureau of Indian Standards, New Delhi
Brammer H (2008) Threat of arsenic to agriculture in India, Bangladesh and Nepal. Econ Polit Wkly 22:79–84
Bundschuh J, Nath B, Bhattacharya P, Liu CW, Armienta MA, Lopez MVM, Lopez DL, Jean JS, Cornejo L, Macedo LFL, Filho AT (2011) Arsenic in the human food chain: the Latin American perspective. Sci Total Environ 429:92–106
Cai Y, Cabarera JC, Georgiadis M, Jayachandran K (2002) Assessment of arsenic mobility in soils of some golf courses in South Florida. Sci Total Environ 291:123–134
Central Ground Water Board (2008) Ground water information booklet, Sahebganj district, Jharkhand state. Ministry of Water Resources (Govt. of India). Mid–Eastern Region, Patna
Chakraborti D, Rahman MM, Paul K, Chowdhury UK, Sengupta MK, Lodh D, Chanda CR, Saha KC, Mukherjee SC (2008) Arsenic calamity in the Indian subcontinent: what lessons have been learned. Talanta 58:3–22
Chakraborty S, Alam MO, Bhattacharya T, Singh YN (2014) Arsenic accumulation in food crops: a potential threat in Bengal Delta Plain. Wat Qual Expos Health 6:233–246
Das HK, Sengupta PK, Hossain A, Islam M, Islam F (2002) Diversity of environmental arsenic pollution in Bangladesh. In: Ahmed MF, Tanveer SA, Badruzzaman ABM (eds) Bangladesh environment, vol 1. Bangladesh Paribesh Andolon, Dhaka, Bangladesh, pp. 234–244
Das HK, Mitra AK, Sengupta PK, Hossain A, Islam F, Rabbani GH (2004) Arsenic concentrations in rice, vegetables and fish in Bangladesh a preliminary study. Environ In. 30:383–387
Divya L, George J, Midhun G (2015) Heavy metal contamination of some common tubers sold in local markets of Ernakulam District, Kerala, India. Int Res J Bio Sci 4(3):49–52
Electronic Work group led by China (2011) Discussion Paper on Arsenic in Rice, Joint FAO/WHO Food standard Programme, Codex committee on contaminants in foods, The Hague, Netherlands (ftp://ftp.fao.org/codex/meetings/cccf/cccf5/cf05_10e.pdf)
Fitz WJ, Wenzel WW (2002) Arsenic transformations in the soil–rhizosphere–plant system: fundamentals and potential application to phytoremediation. J Biotech 99:259–278
Ghosh M, Singh SP (2005) A comparative study of cadmium phytoextraction by accumulator and weed species. Environ Pol 133:365–371
Halder D, Bhowmick S, Biswas A, Chatterjee D, Nriagu J, Guha Mazumder DN, Šlejkovec Z, Jacks G, Bhattacharya P (2012) Risk of arsenic exposure from drinking water and dietary components: implications for risk management in rural Bengal. Environ. Sci Technol 47(2):1120–1127. doi:10.1021/es303522s
Hansel CM, Fendorf S, Sutton S, Newville M (2001) Characterization of Fe plaque and associated metals on the roots of mine-waste impacted aquatic plants. Environ Sci Technol 35:3863–3868
Hsu WM, Hsi HC, Huang YT, Liao CS, Hseu ZY (2012) Partitioning of arsenic in soil–crop systems irrigated using groundwater: a case study of rice paddy soils in southwestern Taiwan. Chemosphere 86:606–613
Huang RQ, Gao SF, Wang WL, Staunton S, Wang G (2006) Soil arsenic availability and the transfer of soil arsenic to crops in suburban areas in Fujian Province, Southeast China. Sci Total Environ 368:531–541
Huq SMI, Alam MD (2005) A handbook on analyses of soil, plant, and water, BACER-DU. University of Dhaka, Bangladesh
Kamal AKI, Islam MR, Hassan M, Ahmed F, Rahman MATMT, Moniruzzaman M (2016) Bioaccumulation of trace metals in selected plants within Amin Bazar landfill site, Dhaka, Bangladesh. Environ Process 3(1):179–194
Kar S, Das S, Jean JS, Chakraborty S, Liu CC (2013) Arsenic in the water-soil-plant system and the potential health risks in the coastal part of Chianan plain, southwestern Taiwan. J Asian Earth Sci 77:295–302
Keon NE, Swartz CH, Brabander DJ, Harvey C, Hemond HF (2001) Validation of an arsenic sequential extraction method for evaluating mobility in sediments. Environ Sci Technol 35:2778–2784
Li QS, Chen Y, Fu HB, Cui ZH, Shi L, Wang LL, Liu ZF (2012) Health risk of heavy metals in food crops grown on reclaimed tidal flat soil in the Pearl River estuary, China. J Hazard Mater 227–228: 148–154
Lin Z, Puls RW (2000) Adsorption, desorption and oxidation of arsenic affected by clay minerals and aging process. Environ Geol 39:753–759
Liu WJ, Zhu YG, Smith SA, Smith SE (2004) Do iron plaque and genotypes affect arsenate uptake and translocation by rice seedlings (Oryza sativa L.) grown in solution culture. J Exp Bot 55(403):1707–1713
Liu J, Qu P, Zhang W, Dong Y, Li L, Wang M (2014) Variations among rice cultivars in subcellular distribution of Cd: the relationship between translocation and grain accumulation. Environ Exp Bot 107:25–31
Loring DH, Rantala RTT (1992) Manual for the geochemical analyses of marine sediments and suspended particulate matter. Earth Sci Rev 32:235–283
Mandal BK, Suzuki KT (2002) Arsenic round the world: a review. Talanta 58:201–235
Meharg AA (2004) Arsenic in rice-understanding a new disaster for South-East Asia. Trends Plant Sci 9:415–417
Meharg AA, Rahman MM (2003) Arsenic contamination of Bangladesh paddy field soils: implications for rice contribution to arsenic consumption. Environ Sci Technol 37:229–234
Misra AK (2011) Impact of urbanization on the hydrology of ganga basin (India. Water Resour Manag 25:705–719
Nayak B, Das B, Mukherjee SC, Pal A, Ahamed S, Hossain MA, Maity P, Dutta RN, Dutta S, Chakraborti D (2008) Groundwater arsenic contamination in Sahibgunj district of Jharkhand state, India in middle ganga plain and adverse health effects. Toxicol Environ Chem 90(4):673–694
Nickson R, Sengupta C, Mitra P, Dave SN, Banerjee AK, Bhattacharya A, Basu S, Kakoti N, Moorthy NS, Wasuja M, Kumar M, Mishra DS, Ghosh A, Vaish DP, Srivastava AK, Tripathi RM, Singh SN, Prasad R, Bhattacharya S, Deverill P (2007) Current knowledge on the distribution of arsenic in groundwater in five states of India. J Environ Sci Health A Tox Hazard Subst Environ Eng 42:1707–1718
Rahman MA, Hasegawa H, Rahman MM, Rahman MA, Miah MAM (2007) Accumulation of arsenic in tissues of rice plant (Oryza sativa L.) and its distribution in fractions of rice grain. Chemosphere 69:942–948
Rauf MA, Hakim MA, Hanafi MM, Islam MM, Rahman GKMM, Panaullah GM (2011) Bioaccumulation of arsenic (As) and phosphorus by transplanting Aman rice in arsenic-contaminated clay soils. Aus JCrop Sci 5(12):1678–1684
Reeves RD, Baker AJM (2000) Phytoremediation of Toxic Metals. Wiley, New York, pp. 193–229
Rezvani M, Zaefarian F (2011) Bioaccumulation and translocation factors of cadmium and lead in Aeluropus littoralis. Aus J Agri Eng 2(4):114–119
Roychowdhury T, Uchina T, Tokunaga H, Ando M (2002) Survey of arsenic in food composits from arsenic affected area of West Bengal, India. Food Chem. Toxic 40:1611–1621
Roychowdhury T, Tokunaga H, Uchino T, Ando M (2005) Effect of arsenic-contaminated irrigation water on agricultural land soil and plants in West Bengal, India. Chemosphere 58:799–810
Shome S, Roy P, Pal M, Bhati M (2014) Variation of adult and weight in India: state and zone wise analysis. Human Biol Review 3(3):242–257
Smith E, Juhasz AL, Weber J (2009) Arsenic uptake and speciation in vegetables grown under greenhouse conditions. Environ Geochem Health 31:125–132
Srivastava S, Sharma YK (2014) Arsenic induced changes in growth and metabolism of Black Gram seedlings (Vigna mungo L.) and the role of phosphate as an ameliorating agent. Environ. Process 1:431–445
Tanvir M, Chowdhury A, Meharg AA, Deacon C, Hossain M, Norton GJ (2012) Hydrogeochemistry and arsenic contamination of groundwater in the Haor basins of Bangladesh. Water Qual Expo Health 4:67–78
Tordoff GM, Baker AJM, Willis AJ (2000) Current approaches to the revegetation and reclamation of metalliferous mine wastes. Chemosphere 41:219–228
US EPA (2012) Arsenic, Inorganic (CASRN 7440–38-2). Integrated Risk Information System, United States Environmental Protection Agency. (http://www.epa.gov/ iris/subst/0278.htm.)
WHO (1993) Guidelines for drinking-water quality, vol 1, 2nd edn. World Health Organization, Geneva
WHO (2012) Exposure to arsenic – World Health Organization (http://www.who.int/ipcs/features/arsenic.pdf)
Yoon J, Cao X, Zhou Q, Ma LQ (2006) Accumulation of Pb, Cu and Zn in native plants growing on a contaminated Florida site. Sci Total Environ 368:456–464
Yuossef FL, Meharg AA (2011) Levels of arsenic and other trace elements in southern Libyan agricultural irrigated soil and non-irrigated soil projects. Water Qual Expo Health 3:79–90
Zhang ZQ, Shu WS, Lan CY, Wong MH (2001) Soil seed bank as an input of seed sources in vegetation of lead/ zinc mine tailings. Restor Ecol 9:1–8
Acknowledgments
The authors would like to acknowledge the Department of Science and Technology, New Delhi for funding the SERB Young Scientist project SR/FTP/ES-2/2013 entitled “Arsenic enrichment in agricultural soils with potential impacts on crops and food security of Sahibganj, Jharkhand, India” for undertaking this study. The authors would also like to express their sincere thanks to Central Instrumentation facility, BIT, Mesra and Department of Environmental Science, University of Kalyani and Wasim Akram Shaikh, PhD scholar, for their help to analyse the samples.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Alam, M.O., Chakraborty, S. & Bhattacharya, T. Soil Arsenic Availability and Transfer to Food Crops in Sahibganj, India with Reference to Human Health Risk. Environ. Process. 3, 763–779 (2016). https://doi.org/10.1007/s40710-016-0184-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s40710-016-0184-9