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ارزیابی خطرپذیری آلودگی عناصر سنگین در خاک ها و برخی محصولات کشاورزی در اطراف شهر و مناطق صنعتی زنجان

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه صنعتی اصفهان

2 دانشگاه صنعتی اصفهان-دانشکده کشاورزی

چکیده

عناصر سنگین ترکیباتی هستند که به طور طبیعی در خاک وجود دارند یا در نتیجه فعالیت‌های انسان وارد خاک می‌شوند. مهم‌ترین مسیر در معرض قرار گرفتن عناصر سنگین مصرف روزانه مواد غذایی است. پژوهش حاضر با هدف تعیین غلظت عناصر سنگین در خاک و برخی محصولات کشاورزی اطراف مناطق شهری و صنعتی زنجان و احتمال خطرپذیری از مصرف آنها انجام گردید. تعداد 75 نمونه خاک سطحی (عمق 0 تا 10 سانتی‌متر) و 101 نمونه از محصولات کشاورزی اطراف مناطق شهری و صنعتی برداشت گردید و تجزیه‌های آزمایشگاهی در نمونه خاک‌ها و گیاهان مختلف انجام شد. میانگین غلظت کل و قابل جذب عناصر به ترتیب برای مس 4/52 و 47/4، روی 8/264 و 15/23، سرب 7/105 و 81/16، نیکل 7/47 و 20/1 و کروم کل 7/21 میلی-گرم برکیلوگرم خاک به دست آمد. همچنین غلظت عناصر سنگین در گیاهان مختلف نشان داد که سبزیجات بیشترین سهم را در جذب و انباشت فلزات نشان می‌دهند. بالاترین مقادیر Zn (شاهی)، Pb (شوید)، Cu (تره)، Ni (ریحان) و Cr (ریحان) به ترتیب با غلظت‌های 25/150، 25/41، 13/23، 46/6 و 47/3 میلی‌گرم برکیلوگرم و کمترین مقدار فلزات مورد بررسی در میوه سیب و بذر گندم و جو مشاهده شد. به صورت کلی میزان جذب فلزات در گیاهان مختلف بدین صورت بدست آمد (Zn>>Pb>Cu>Ni>Cr). فاکتور تجمعی (BAF) فلزات در گیاهان به ترتیب Zn=Cu>Pb>>Cr>Ni حاصل شد. احتمال خطرپذیری (HQ) به بیماری‌های غیرسرطانی برای هر یک از عناصر (به جز سرب) در دو گروه سنی کودکان و بزرگسالان کم‌تر از یک به دست آمد که نشان می‌دهد مصرف‌کنندگان از این محصولات در محدوده امن از نظر تأثیرات سوء بیماری‌های غیرسرطانی قرار گرفتند. همچنین مقدار احتمال خطرپذیری کل (THQ) در کودکان بیشتر از بزرگسالان بدست آمد.

کلیدواژه‌ها

عنوان مقاله [English]

Risk Assessment of Heavy Metals Contamination in Soils and Selected Crops in Zanjan Urban and Industrial Regions

نویسندگان [English]

  • A. Afshari 1
  • H. Khademi 1
  • shamsollah Ayoubi 2

1 Isfahan University of Technology

2

چکیده [English]

Introduction: Heavy metals are types of elements naturally present in soil or enter into soil as a result of human activities. The most important route of exposure to heavy metals is daily intake of food. Crops grown in contaminated soil (due to mining activities, industrial operations and agriculture) may contain high concentrations of heavy metals. Also closeness to cities and industrial centers can have a great influence on the accumulation of heavy metals to agricultural products grown in the region. The study aimed to determine the concentration of heavy metals in soil and agricultural products around urban and industrial areas of Zanjan province (North West of Iran) and consumption hazard probability.
Materials and Methods: Soil (75 samples of soil from a depth of 0 to 10 cm) and plant (101 samples) samples, in the summer 2011, were randomly taken from industrial areas as follow: tomatoes (Lycopersicum esculentum M), wheat seed (Triticum vulgare), barley seeds (Hordeum vulgare), alfalfa shoots (Medicago sativa L.), potato tubers (Solanumtuberosum L.), apple fruit, vegetables and fruits such as Dill (Aniethum graveolens L.), leek (Allium porrum L.), Gardencress (Barbara verna L.) and basil (Ocimum basilicum L.). Plant samples were then washed with distilled water, oven dried for48 hours at a temperature of 70 ´C until constant weight was attained and then they digested using 2 M hydrochloric acid (HCl) and nitric acid digestion in 5 M. Concentrations of heavy metals in the soil and crops were determined by atomic absorption spectrometry. DTPA extraction of metals by Lindsay and Norvell (1978) method and sequential extraction method by Tessier et al. (1979) were performed. Statistical analysis was accomplished using the software SPSS 16.0 and the comparison of mean values was done using the Duncan test at the 5% level of significance.
Results and Discussion: The magnitude of variations for total copper was from 11.5 to 352.5 (average 52.4), zinc was from 96.3 to 1353.8 (average 264.8), lead was between 40.0 and 470.0 (average 105.7), nickel ranged from 12.8 to 77.0 (average 46.7) and chromium varied from 10.0 to 49.5 (average 21.7) mg kg-1. DTPA extracted heavy metals for copper varied from 1.50 to 21.23, averaging 4.47, zinc from 0.57 to 76.50 averaging 23.15, lead from 2.43 to 63.38 averaging 16.81 and nickel from 0.28 to 2.32 averaging 1.20 mg kg-1. Chemical changes in the different fractions were as follows: Cu (residual > bounded to organic matter > bounded to Fe-Mn oxides > bounded to carbonate > exchangeable fraction), Zn and Ni (residual > bounded to Fe-Mn oxides > bounded to carbonate > bounded to organic matter > exchangeable fraction,) and Pb (residual > bounded to Fe-Mn oxides > bounded to organic matter > bounded to carbonate > exchangeable fraction). The concentration of heavy metals in plant parts were high with respect to studied location. The highest amounts of Zn (Gardencress), Pb (Dill), Cu (Leek), Ni (Basil) and Cr (Basil), respectively were found to be 150.25, 41.25, 23.13, 6.46 and 3.47 mg kg-1 and the minimum amounts of the metals studied were found in fruits, wheat and barley grains. The total amount of metals in plants were as follow (Zn >> Pb > Cu > Ni > Cr). Bioaccumulation factor (BAF) of metals in plants were as Zn=Cu > Pb >> Cr > Ni. Hazard probability (HQ) in cancerous diseases for each element (except Pb) in both children and adults was less than unit. HQ content of Pb was much higher than the unit and for children and adults 9.07 and 6.94, respectively showing high contribution of Pb contamination of crops that threatens the consumer health in that location. The total amount of risk (THQ) in children was higher than that in adults.
Conclusions: The results obtained in this study indicate that an urgent attention is required for consumer products related to public health, especially vegetables grown in the studied regions. Toxic effects of heavy metals have many deleterious effects which are more pronounced over time. With conventional monitoring of food quality produced in farms and presented in markets, excessive accumulation of heavy metals entering in to the human food chain can be prevented. Also, we can change the risk potential of heavy metals in the region by growing vegetables which accumulate heavy metals.
Keywords: Agriculture products, Biological risk, Heavy metals, Soil, Zanjan province

کلیدواژه‌ها [English]

  • Agriculture products
  • Biological risk
  • Heavy metals
  • Soil
  • Zanjan province
مراجع
1- Beigi Harchegani H., and Banitalebi G. 2013. The effect of twenty-three years of surface irrigation with treated municipality wastewater on soil loadings, transfer to wheat and corn grains, and related health risks of some heavy metals. Journal of Water and Soil, 27 (3): 570-580. (in Persian with English Abstract)
2- Bi X.Y., Feng X.B., Yang Y.G., Li X.D., Shin G.P.Y., Li F.L., Qiu G.L., Li G.H., Liu T.Z., and Fu Z.Y. 2009. Allocation and source attribution of lead and cadmium in maize (Zeamays L.) impacted by smelting emissions. Environmental Pollution, 157: 834-839.
3- Bo S., Mei L., Tongbin C., Yuanming Z., Yunfeng X., Xiaoyan L., and Ding G. 2009. Assessing the health risk of heavy metals in vegetables to the general population in Beijing, China. Journal of Environmental Sciences, 21: 1720-1709.
4- Boon D.Y., and Soltanpour P.N. 1992. Lead, cadmium and zinc contamination of aspen garden soils and vegetation. Environmental Quality, 21: 82-86.
5- Burt R. 2004. Soil survey laboratory methods manual, soil survey investigations, report No. 42, Version 4.0, USDA, Natural Resources Conservation Service, Lincoln, NE, USA.
6- Chary N.S., Kamala C.T., Raj S.S. 2008. Assessing risk of heavy metals from consuming food grown on sewage irrigated soils and food chain transfer. Ecotoxicology and Environmental Safety, 69: 513-524.
7- DeFlora S., Camoirano A., Bagnasco M., Bennicelli C., Corbett G.E., and Kerger B.D. 1997. Estimates of the chromium (VI) reducity in human body compartments as a mechanism for attenuating its potential toxicity and carcinogenicity. Carcinogenesis, 18: 531-537.
8- Ferre-Huguet N., Marti-Cid R., Schuhmacher M., and Domingo J.L. 2008. Risk assessment of metals from consuming vegetables, fruits and rice grown on soils irrigated with waters of the Ebro River in Catalonia, Spain. Biol Trace Elem Res, 123: 66-79.
9- Gruda N. 2005. Impact of environmental factors on product quality of greenhouse vegetables for fresh consumption. Critical Reviews in Plant Sciences, 24: 227-247.
10- Haiyan W., and Stuanes A.O. 2003.Heavy metal pollution in air-water-soil-plant system of Zhuzhou city, Hunan province, China. Water, Air, and Soil pollution, 147: 79-107.
11- Hang X., Wang H., Zhou J., Ma C., Du C., and Chen X. 2009. Risk assessment of potentially toxic element pollution in soils and rise (Oryza sativa) in a typical area of the Yangteze River Delta. Environmental Pollution, 157: 2542-2549.
12- Hoodaji M., and Jalalian A. 2004a. Distribution of Nickel, Manganese and Cadmium in Soil and Crops in the Mobarakeh Steel Plant Region. JWSS - Isfahan University of Technology. 8 (3):55-67. (In Persian with English Abstract)
13-Hoodaji M., and Jalalian A. 2004b. Distribution of Fe, Zn and pb in Soil and Crops in the Mobarakeh Steel Plant Region. Journal of Environmental Studied. 36: 15-26 (In Persian)
14- Huang M., Zhou S., Sun B., and Zhao Q. 2008. Heavy metals in wheat grain: assessment of potential health risk for inhabitants in Kunshan, China. Science of the Total Environment, 405: 54-61.
15- Jia L., Wang W., Li Y., and Yang L. 2010. Heavy metals in soil and crops of an intensively Farmed area: A case study in Yucheng city, Shandong province, China. International Journal of Environmental Research and Public Health, 7: 395-412.
16- Joint FAO/WHO export committee on food additives. Summary and conclusions, 53rd meeting. Rome: Joint FAO/WHO, 1999. Technical Report.
17- Kabata-Pendias A., and Pendias H. 2001. Trace elements in soils and plants. Third Ed. CRC Press. Boca Raton, London.
18- Karami M., Afyuni M., Rezainejad Y., and Schulin R. 2009. Heavy metal uptake by wheat from a sewage sludge-amended calcareous soil.NutrCyclAgroecosyst. 83: 51-61.
19-Kheirabadi H., Afyuni M., Barzin M., Soffianian A., and Ayoubi Sh. 2012.Evaluation risk assessment of heavy metal in potato and wheat consumption in the Hamadan Province.12th Congress of Soil Science, 12-14 August, Tabriz, Iran.(In Persian)
20- Li, X., and Feng, L. 2012. Multivariate and geostatistical analyzes of metals in urban soil of Weinan industrial areas, Northwest of China. Atmospheric Environment, 47: 58-65.
21- Lindsay W.L., and Norvell W.A. 1978. Development of DTPA test for zinc, iron, manganese, and copper. Soil Science Society of American Journal, 42: 421-428.
22- Luo C., Liu C., Wang Y., Liu X., Li F., Zhang G., and Li X. 2011. Heavy metal contamination in soils and vegetable near an e-waste processing site, south China. Journal of Hazardous Materials, 186: 481-490.
23- Martines L.L., and Mourato P.M. 2006. Effect of excess copper on tomato plants: Growth parameters, enzyme, chlorophyll, and mineral content. J Plant Nutr, 29: 2179-2198.
24- Nannoni F., Protano G. and Riccobono F. 2011. Fractionation and geochemical mobility of heavy elements in soils of a mining area in northern Kosovo.Geoderma, 161: 63-73.
25- National environmental protection agency of China. 2001. Safety quality standard for non-environmental pollution vegetable (GB/T 18407.1-2001).
26-Nazemi S., Asgari A.R., and Raei M .2010. Survey the amount of heavy metals in cultural vegetables in suburbs of Shahroud. Iran J. Health & Environ, 3 (2): 195-202. (In Persian with English Abstract)
27- Qian Y.Z., Chen C., Zhang Q., Li Y., Chen Zhijan, and Li M. 2010. Concentration of cadmium, lead, mercury and arsenic in Chinese market milled rice and associated population health risk. Food Control, 21: 1757-1763.
28- Qishlaqi A., Moor F., and Forghani G. 2008. Impact of untreated wastewater irrigation on soil and crops in Shiraz suburban area, SW Iran. Environmental Monitoring Assessment, 141: 257-273.
29- Rashed N. 2010. Monitoring of contamination toxic and heavy metals, from mine tailings through age accumulation, in soil and some wild.Journal of Hazardous Materials, 178: 739-746.
30- Robson M. 2003. Methodologies for assessing exposures to metals: human host factors. Ecotoxicology and Environmental Safety, 56: 104-109.
31- Sposito G., Land L.J., and Chang A.C. 1982. Trace metal chemistry in aird-zone field soils amended with sewage sludge: I .Fractionation of Ni, Cu, Zn, Cd and Pb in solid phases. Soil Science Society of American Journal, 46: 260-264.
32- Tessier A., Campbell P.G.C., and Bisson M. 1979. Sequential extraction procedures for the speciation of particulate trace metals. Analytical Chemistry, 51: 844-851.
33-Torabian A., and Mahjouri M 2002. Heavy metals uptake by vegetable crops irrigated with wastewater in south Tehran. Science of Soil and Water, 16 (2): 188-196. (In Persian with English Abstract)
34- USEPA (US Environmental Protection Agency). 1989. Risk assessment guidance for superfund. Human health evaluation manual part A. EPA/540/1-89/002.Office of health and environmental assessment, Washington, DC, USA.
35- USEPA, IRIS 2006. United States, Environmental Protection Agency, Integrated Risk Information System. http://www.epa.gov/iris/subst.
36- Wang X., Sato T., Xing B., and Tao S. 2005. Health risks of heavy metals to the gereral public in Tianjin, China via consumption of vegetables and fish. Science of the Total Environment, 350: 28-37.
37- Wanger G.L. 1993. Accumulation of cadmium in crop plants and its consequences to human health. Adv. Agron. 51: 173-212.
38- Wilde S.A., Corey R.B., and Iyer J.G. 1979. Soils and plant analysis for tree culture.Part 3.Analysis of plant tissue. Oxford and IBH, New Delhi, pp 93-106.
39- Zhao F.J., Su Y.H., Dunham S.J., Rakszegi M., Bedo Z., McGrath S.P., Shewry P.R. 2009. Variation in mineral micronutrient concentrations in grain of wheat lines of diverse origin. Journal of Cereal Science, 49: 290-295.
40- Zheng N., Wang Q., and Zheng D. 2007. Health risk of Hg, Pb, Cd, Zn, and Cu to the inhabitants around Huludao Zinc plant in China via consumption of vegetables. Science of the Total Environment, 383: 81-89.
41- Yu G.B., Liu Y., Yu S., Wu S.C., leung A.O.W., Luo X.S., Xu B., Li H.B. and Wong M.H. 2011. Inconsistency and comprehensiveness of risk assessments for heavy metals in urban surface sediments. Chemosphere, 85: 1080-1087.
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آب و خاک
دوره 29، شماره 1 - شماره پیاپی 1
فروردین و اردیبهشت 1394
صفحه 151-163
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  • تاریخ دریافت: 12 آبان 1392
  • تاریخ پذیرش: 12 آبان 1392
  • تاریخ اولین انتشار: 01 فروردین 1394
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