Investigating the phytoavailability of trace elements in contaminated agricultural soils and health risks via consumption of water spinach grown under field conditions in Zhuzhou, China
详细信息 查看全文
- 作者:Jining Li ; Hong Hou ; Yuan Wei ; Long Zhao ; Juan Zhang…
- 关键词:Trace elements ; Phytoavailability ; Agricultural soils ; Health risk ; Water spinach
- 刊名:Environmental Earth Sciences
- 出版年:2016
- 出版时间:March 2016
- 年:2016
- 卷:75
- 期:5
- 全文大小:1,095 KB
- 参考文献:Baraud F, Leleyter L (2012) Prediction of phytoavailability of trace metals to plants: comparison between chemical extractions and soil-grown radish. C R Geosci 344:385–395CrossRef
Baziramakenga R, Simard RR, Leroux GD (1995) Determination of organic acids in soil extracts by ion chromatography. Soil Biol Biochem 27:349–356CrossRef
Bhuiyan MAH, Parvez L, Islam MA, Dampared SB, Suzukia S (2010) Heavy metal pollution of coal mine-affected agricultural soils in the northern part of Bangladesh. J Hazard Mater 173:384–392CrossRef
Bi XY, Feng XB, Yang YG, Li XD, Shin GPY, Li FL et al (2009) Allocation and source attribution of lead and cadmium in maize (Zea mays L.) impacted by smelting emissions. Environ Pollut 157:834–839CrossRef
Black A, McLaren RG, Reichman SM, Speir TW, Condron LM (2011) Evaluation of soil metal bioavailability estimates using two plant species (L. perenne and T. aestivum) grown in a range of agricultural soils treated with biosolids and metal salts. Environ Pollut 159:1523–1535CrossRef
Broadley MA, Willey NJ, Wilkins JC, Baker AJM, Mead A, White PJ (2001) Phylogenetic variation in heavy metal accumulation in angiosperms. New Phytol 152:9–27CrossRef
Cai L, Xu ZC, Ren MZ, Guo QW, Hu XB, Hu GC et al (2012) Source identification of eight hazardous heavy metals in agricultural soils of Huizhou, Guangdong Province, China. Ecotoxicol Environ Saf 78:2–8CrossRef
Cao HB, Chen JJ, Zhang J, Zhang H, Qiao L, Men Y (2010) Heavy metals in rice and garden vegetables and their potential health risks to inhabitants in the vicinity of an industrial zone in Jiangsu, China. J Environ Sci 22:1792–1799CrossRef
Elbana TA, Ramadan MA, Gaber HM, Bahnassy MH, Kishk FM, Selim HM (2013) Heavy metals accumulation and spatial distribution in long term wastewater irrigated soils. J Environ Chem Eng 1:925–933CrossRef
Feng MH, Shan XQ, Zhang SZ, Wen B (2005) A comparison of the rhizospherebased method with DTPA, EDTA, CaCl2, and NaNO3 extraction methods for prediction of bioavailability of metals in soil to barley. Eviron Pollut 137:231–240CrossRef
Fox TR, Comerford NB (1990) Low-molecular-weight organic acids in selected forest soils of the southeastern USA. Soil Sci Soc Am J 54:1139–1144CrossRef
Gebrekidan A, Weldegebriel Y, Hadera A, Van der Bruggen B (2013) Toxicological assessment of heavy metals accumulated in vegetables and fruits grown in Ginfel river near Sheba Tannery, Tigray, Northern Ethiopia. Ecotoxicol Environ Saf 95:171–178CrossRef
Göthberg A, Greger M, Bengtsson BE (2002) Accumulation of heavy metals in water spinach (Ipomoea aquatica) cultivated in the Bangkok region, Thailand. Environ Toxicol Chem 21:1934–1939CrossRef
Hou H, Takamatsu T, Koshikawa MK, Hosomi M (2005) Concentrations of Ag, In, Sn, Sb and Bi, and their chemical fractionation in typical soils in Japan. Eur J Soil Sci 2:214–227
Hseu ZY, Jien SH, Wang SH, Deng HW (2006) Using EDDS and NTA for enhanced phytoextraction of Cd by water spinach. J Environ Manage 117:58–64CrossRef
Huang SS, Liao QL, Hua M, Wu XM, Bi KS, Yan CY et al (2007) Survey of heavy metal pollution and assessment of agricultural soil in Yangzhong district, Jiangsu Province, China. Chemosphere 67:2148–2155CrossRef
Lakanen E, Erviö R (1971) A comparison of eight extractants for the determination of plant available micronutrients in soils. Acta Agric Fenn 128:223–232
Lei M, Zeng M, Zheng YM, Liao MH, Zhu Y (2008) Heavy metals pollution and potential ecological risk in paddy soils around mine areas and smelting areas in Hunan Province. Acta Sci Circumst 6:1212–1220 (in Chinese)
Li ZG, Feng XB, Li GH, Bi XY, Sun GY, Zhu JM et al (2011) Mercury and other metal and metalloid soil contamination near a Pb/Zn smelter in east Hunan province, China. Appl Geochem 26:160–166CrossRef
Li Y, Gou X, Wang G, Zhang Q, Su Q, Xiao GJ (2008) Heavy metal contamination and source in arid agricultural soil in central Gansu Province, China. J Environ Sci 20:607–612CrossRef
Liu GN, Tao L, Liu XH, Hou J, Wang AJ, Li RP (2013) Heavy metal speciation and pollution of agricultural soils along Jishui River in non-ferrous metal mine area in Jiangxi Province, China. J Geochem Explor 132:156–163CrossRef
Lu AX, Wang JH, Qin XY, Wang KY, Han P, Zhang SZ (2012) Multivariate and geostatistical analyses of the spatial distribution and origin of heavy metals in the agricultural soils in Shunyi, Beijing, China. Sci Total Environ 425:66–74CrossRef
Luo CL, Liu CP, Wang Y, Liu X, Li FB, Zhang G, Li XD (2011) Heavy metal contamination in soils and vegetables near an e-waste processing site, south China. J Hazard Mater 186:481–490CrossRef
Luo XS, Yu S, Li XD (2012) The mobility, bioavailability, and human bioaccessibility of trace metals in urban soils of Hong Kong. Appl Geochem 27:995–1004CrossRef
Luo XS, Zhou DM, Liu XH, Wang YJ (2006) Solid/solution partitioning and speciation of heavy metals in the contaminated agricultural soils around a copper mine in eastern Nanjing city, China. J Hazard Mater 131:19–27CrossRef
Martin R, Antonio J, Arias L (2006) Heavy metals contents in agricultural topsoils in the Ebro basin (Spain). Application of the multivariate geoestatistical methods to study spatial variations. Environ Pollut 144:1001–1012CrossRef
Meers E, Samson R, Tack FMG, Ruttens A, Vandegehuchte M, Vangronsveld J et al (2007) Phytoavailability assessment of heavy metals in soils by single extractions and accumulation by Phaseolus vulgaris. Environ Exp Bot 60:385–396CrossRef
Menzies NW, Donn MJ, Kopittke PM (2007) Evaluation of extractants for estimation of the phytoavailable trace metals in soils. Environ Pollut 145:121–130CrossRef
Ministry of Health of China (2008) Health Statistical Yearbook of China 2008. Ministry of Health of China
Micó C, Recatalá L, Peris M, Sánchez J (2006) Assessing heavy metal sources in agricultural soils of an European Mediterranean area by multivariate analysis. Chemosphere 65:863–872CrossRef
Mourier B, Fritsch C, Dhivert E, Gimbert F, Cœurdassier M, Pauget B et al (2011) Chemical extractions and predicted free ion activities fail to estimate metal transfer from soil to field land snails. Chemosphere 85:1057–1065CrossRef
Rattan RK, Datta SP, Chhonkar PK, Suribabu K, Singh AK (2005) Long-term impact of irrigation with sewage effluents on heavy metal content in soils, crops and groundwater—a case study. Agric Ecosyst Environ 109:310–322CrossRef
Rukun L (2000) Method of soil agrochemical analysis. Chinese Agricultural Science and Technology Press, Beijing (in Chinese)
Song J, Guo Z, Xiao X, Miao X, Wang F (2009) Environmental availability and profile characteristics of arsenic, cadmium, lead and zinc in metal-contaminated vegetable soils. Trans Nonferrous Met Soc China 3:765–772CrossRef
State Environmental Protection Administration (2006) Farmland environmental quality evaluation standards for edible agriculture products HJ332-2006. State Environmental Protection Administration, China
Sun CY, Liu JS, Wang Y, Sun LQ, Yu HW (2013) Multivariate and geostatistical analyses of the spatial distribution and sources of heavy metals in agricultural soil in Dehui, Northeast China. Chemosphere 92:517–523CrossRef
Symeonides C, McRae SG (1977) The assessment of plant-available cadmium in soils. J Environ Qual 6:120–123CrossRef
Tariq SR, Bashir A (2012) Speciative distribution and bioavailability of metals in agricultural soils receiving industrial wastewater. Environ Monit Assess 184:4609–4622CrossRef
Tiwari KK, Singh NK, Patel MP, Tiwari MR, Rai UN (2011) Metal contamination of soil and translocation in vegetables growing under industrial wastewater irrigated agricultural field of Vadodara, Gujarat, India. Ecotoxicol Environ Saf 74:1670–1677CrossRef
Voutsa D, Grimanis A, Samara C (1996) Trace elements in vegetables grown in an industrial area in relation to soil and air particulate matter. Environ Pollut 94:325–335CrossRef
Wang XP, Shan XQ, Zhang SZ, Wen B (2004) A model for evaluation of the phytoavailability of trace elements to vegetables under the field conditions. Chemosphere 55:811–822CrossRef
Wang G, Su MY, Chen YH, Lin FF, Luo D, Gao SF (2006) Transfer characteristics of cadmium and lead from soil to the edible parts of six vegetable species in southeastern China. Environ Pollut 144:127–135CrossRef
Wang J, Zhang CB, Jin ZX (2009) The distribution and phytoavailability of heavy metal fractions in rhizosphere soils of Paulowniufortunei (seem) Hems near a Pb/Zn smelter in Guangdong, PR China. Geoderma 148:299–306CrossRef
Wong SC, Lia XD, Zhang G, Qi SH, Min YS (2002) Heavy metals in agricultural soils of the Pearl River Delta, South China. Environ Pollut 119:33–44CrossRef
Xu DC, Zhou P, Zhan J, Gao Y, Dou CM, Sun QY (2013) Assessment of trace metal bioavailability in garden soils and health risks via consumption of vegetables in the vicinity of Tongling mining area, China. Ecotoxicol Environ Saf 90:103–111CrossRef
Yang SL, Zhou DQ, Yu HY, Wei R, Pan B (2013) Distribution and speciation of metals (Cu, Zn, Cd, and Pb) in agricultural and non-agricultural soils near a stream upriver from the Pearl River, China. Environ Pollut 177:64–70CrossRef
Zhang HB, Luo YM, Makino T, Wu LH, Nanzyo M (2013) The heavy metal partition in size-fractions of the fine particles in agricultural soils contaminated by waste water and smelter dust. J Hazard Mater 248:303–312CrossRef
Zhao QH, Wang Y, Cao Y, Chen AG, Ren M, Ge YS et al (2014) Potential health risks of heavy metals in cultivated topsoil and grain, including correlations with human primary liver, lung and gastric cancer, in Anhui province, Eastern China. Sci Total Environ 470:340–347CrossRef
Zurera-Cosano G, Moreno-Rojas R, Salmeron-Egea J, Pozo Lora R (1989) Heavy metal uptake from greenhouse border soils for edible vegetables. J Sci Food Agric 49:307–314CrossRef - 作者单位:Jining Li (1)
Hong Hou (1)
Yuan Wei (1)
Long Zhao (1)
Juan Zhang (1)
Yuxian Shangguan (1)
Yafei Xu (1)
Zengguang Yan (1)
Fasheng Li (1)
1. State Key Laboratory of Environmental Criteria and Risk Assessment, Chinese Research Academy of Environmental Sciences, Dayangfang 8, Beijing, 100012, People’s Republic of China - 刊物类别:Earth and Environmental Science
- 刊物主题:None Assigned
- 出版者:Springer Berlin Heidelberg
- ISSN:1866-6299
文摘
In this study, the phytoavailability of trace elements from contaminated agricultural soils to water spinach grown under field conditions in Zhuzhou, China was investigated using three single extraction methods: CaCl2, HAc, and acid ammonium acetate-EDTA (AEDTA) compared with a strong acid digestion method. The soils are primarily contaminated by Cd (4.16 ± 5.98 mg kg−1) and Pb (152 ± 160 mg kg−1), followed by Zn (403 ± 443 mg kg−1), Cu (60.5 ± 29.4 mg kg−1) and As (39.1 ± 36.0 mg kg−1). The main pollutants in water spinach grown in this area are Pb and Cd. The estimated dietary intakes of Cd, Pb and As in some sampling sites were higher than the tolerable limits, indicating that the potential health risks from exposure to these three elements through consumption of water spinach need more attention. Importantly, water spinach has an increased propensity for Cd phytoextraction in contaminated soils with an average bioaccumulation factor of higher than 1, whereas Pb in the edible parts of water spinach is probably present from atmospheric deposition. Statistical analysis indicated that more aggressive extraction procedures (HAc or AEDTA) were better able to predict the phytoavailability of trace elements. Moreover, the phytoavailability of Pb, Cd and Zn could also be well predicted by their total concentrations in soils. Although the trace elements content in water spinach could mostly be explained by total or extractable concentrations, the regression predictions were further improved by the incorporation of soil properties.