Pollution Index and Ecological Risk of Heavy Metals in the Surface Soils of Amir-Abad Area in Birjand City, Iran

authors:

avatar Mohammad Hossein Sayadi 1 , * , avatar Mehri Shabani 1 , avatar Najmeh Ahmadpour 1

Department of Environment, School of Natural Resources and Environment, University of Birjand, Birjand, IR Iran

how to cite: Sayadi M H, Shabani M, Ahmadpour N. Pollution Index and Ecological Risk of Heavy Metals in the Surface Soils of Amir-Abad Area in Birjand City, Iran. Health Scope. 2015;4(1):ee21137. https://doi.org/10.17795/jhealthscope-21137.

Abstract

Background:

In the present era, the concentration of heavy metals in the environment is increasing. Due to the deleterious effects of these metals on human health as well as their dangerous consequences on ecosystem, special attention should be paid to remove them from the environment.

Objectives:

The purpose of this study was to assess the ecological risk of heavy metals including lead (Pb), cadmium (Cd), copper (Cu), zinc (Zn), chromium (Cr) in surface soils of an Amir-Abad Area in Birjand City, Iran.

Materials and Methods:

Soil Samples were collected from a depth of 0-20 cm at 16 stations with different users. The samples were passed through a 2-mm sieve after air drying. To determine the concentration of heavy metals, the samples were extracted by acid chloride and nitric acid and total concentrations of toxic elements were read using the atomic absorption spectrophotometry. The pollution index and ecological risk assessments were calculated for each element.

Results:

The results showed that the ecological risk of surface soil for the users of the road-residential was high (1370.72) and notable (505.04), and the agricultural land use and livestock had the moderate ecological risk and dairy farm had low ecological risk. When the results of this study were compared to world standards, it was suggested that the areas with the road-residential areas were considered to be dangerous to health; this was directly related to developments of technology and pollution.

Conclusions:

It can be concluded that residential-road land uses show the considerable pollution index and ecological risk.

1. Background

An ecological risk assessment is the process to evaluate the likeliness of an environment to be impacted as a result of exposure to one or more environmental stressors. It is a flexible process, not only to organize and analyze data, information, assumptions, and uncertainties but also evaluate the likelihood of adverse ecological effects (1). However, the heavy metals are included as earth's crust forming components and also are naturally present all around the ecosystem. Their concentration can considerably increase via human activities (2). Nevertheless, many researchers have studied the adverse effects of heavy metals on various ecosystems in the past two decades.

Different human activities can contaminate urban soils. As an example, the transportation of goods and passengers (3), industries, factories and mining (4), agriculture (5), livestock (6), dust (7), municipal waste (8) can be specified.

Innumerable studies have been carried out worldwide related to the soil pollution importance and its negative impact on population health and the environment, such as Ireland (9), Italy (10), Spain (11), Zimbabwe (12), Australia (13), China (14) and also in some Iranian cities like Tehran (15), Isfahan (16), Hamadan (17) and Birjand (6).

Exposure to dust containing heavy metals leads to varied issues, including physical and mental retardation, decreased intelligence quotient, reduced concentration, headaches, cancer, increased blood pressure, renal and liver problems related to the nervous system, general weakness, and dysfunction of internal organs or aggravates via other diseases, and in some cases leads to death (18).

The study area was located on the west side of Birjand, 5 km off Birjand-Kerman road in South Khorasan Province. The potential sources of pollutants in this area were from agriculture and animal husbandry activities, urban activities, the presence of small shops and casual works and also passing one of the main roads of province along this residential area. There is also an industrial estate that can be considered as one of the essential human pollutant sources in environment (17).

2. Objectives

The purpose of this study was to assess the pollution index and ecological risk of heavy metals including lead (Pb), cadmium (Cd), copper (Cu), zinc (Zn) and chromium (Cr) in surface soils of the Amir-Abad Area, Birjand City, Iran.

3. Materials and Methods

3.1. Sampling

As the Figure 1 shows, the grid map is used to select the samples in the study area. Five sampling points at each sampling station (fourat the corners and one at the center of the grid) were collected.

Mapof the Study Area With Sampling Stations
Mapof the Study Area With Sampling Stations

The samples were collected at 16 stations with different land uses between 0 and 20 cm soil depths, at each station, 5 samples with 3 replications were collected using the plastic spatula after removing the debris, rock pieces and physical contaminants.

A composite sample of 1.5 kg weight was prepared after mixing the 5 samples obtained from each station. Geographical locations of points were determined by global positioning systems. The samples were passed through a 2-mm sieve after air drying and to determine the concentration of heavy metals, the samples were extracted by acid chloride and nitric acid and total concentrations of toxic elements were read using the atomic absorption spectrophotometry (18).

3.2. Calculation of Ecological Risk

The ecological risks of heavy metals were calculated using the following equations (19).

Equation 1.
Equation 2.
Equation 3.

Where"Cs" is the concentration of study metals, "Bn"is natural background value. "PI"is contamination index, "Er" is the indicator of each element’s ecological risk and RI is the determinative of the total ecological risk.

The toxic response factor for a given compoundisshown by "Tr", "Er" is the potential risk index for given substance and "RI" is the potential ecological risk index for each area.

The results were analyzed after calculating the ecological risk for each element and the total ecological risk was evaluated. The following ranges of "RI" values were considered in the present study; low ecological risk RI < 150, moderate ecological risk 150 ≤ RI < 300, high ecological risk 300 ≤ RI < 600 and considerable ecological risk RI > 600 (19).

To calculate the background values in different studies, these values were chosen from previous researches (15), and to assess the amount of ecological risk, the "RI" and "Er" values were calculated using the equation2.

4. Results

The toxic metals via human activities can lead to soil pollution. These heavy metals are one of the most important pollutants that can cause serious problems to human health, plants and other organisms by entering the food chains (4). Table 1 depicts the comparison between the average concentration of the elements in the study area and the average concentration in the earth's crust. The results showed that the concentration of all elements except Cr were higher than the average of background values.

Table 1.

Average Concentrations of Heavy Metals in This Study and Earth Crust Level a

Zn, mg/kgCr, mg/kgPb, mg/kgCd, mg/kgCu, mg/kg
Surface soil in present study94.09 ± 38.663.79 ± 11.546.59 ± 12.41.53 ± 0.760.15 ± 11.4
Earth's crust (15)75100140.250

Equation 1 was used to assess the ecological risk of soil pollution via pollution index. Contamination levels were classified into six categories based on the pollution severity.

Table 2.

Classification of Pollution Index

Pollution LevelsAmounts
Unpolluted0
Unpolluted- moderate1
Moderate pollution2
Moderate-high pollution3
High pollution4
High-very high pollution 5
Very high pollution6

The results in Table 3 showed that most of the samples indicated low to moderate pollution. However, some users, especially residential-road areas demonstrated very high pollution.

Table 3.

Pollution Index in the Case Study Area a, b

Station NumberLand useCoordinatesCdCrZnCuPb
NE
1Dairy farm32.86059.1416.50.84.63.31.4
2Natural land35.86159.1430.30.20.40.31
3Natural land32.85959.15330.20.30.20.9
4Natural land32.85559.1584.10.20.30.21.1
5Natural land32.86559.1421.80.30.20.41.2
6Educational center32.86659.1438.50.60.80.42
7Road32.86759.1433.50.21.70.84.5
8Road32.86259.1582.20.71.20.84.7
9Residential- road32.86959.14514.61.91.64.57.9
10Residential- road32.86559.14342.91.91.64.111.9
11Residential-agriculture32.6559.15180.61.513.2
12Agriculture32.86859.1582.30.61.10.64.2
13Residential-agriculture32.87859.1385.10.41.40.73.6
14Residential-agriculture32.87959.1424.70.41.70.92.4
15Agriculture32.88059.1527.30.90.90.51.6
16Agriculture32.88159.1557.60.30.70.51.8

5. Discussion

The results of varied concentrations and their respective ecological risks are shown in Table 4. The average lead concentration was 59.46 mg/kg, which was higher than its average in the earth's crust. The concentration of Pb was higher than the earth’s crust in all the stations except stations 2 and 3 (Tables 1 and 2). Generally, lead is released from smelting, motor-vehicle exhaust fumes and corrosions of lead pipe work (20).

The average copper concentration was 60.15 mg/kg, which was higher than its relative concentration in the earth’s crust. However, this was true only for the station 2 and 10 (Tables 1 and 4). Both these stations caused the total concentration of this element to overpass than its average in the earth’s crust. Cupper is extensively utilized in electrical cables, cooking appliances, pipes, chemical factories, metal melting furnaces, pigments and fertilizers (21). Although it is one of the essential elements for humans, but its overdoses could lead to neurological complications, hypertension, liver and kidney dysfunctions and even death (22).

Table 4.

Concentration of Elements and the Ecological Risk of Samples a, b

StationPbCuZnCrCd
Concentration, mg/kgEraconcentration, mg/kgErConcentration, mg/kgErConcentration, mg/kgErConcentration, mg/kgErRIaEcological Risk
119.4 ± 4.26.9165.1 ± 74.716.5346.5 ± 201.34.681.7 ± 24.81.61.3 ± 0.4195225moderate
213.9 ± 6.34.917.1 ± 5.51.733 ± 11.80.415.42 ± 8.60.30.05 ± 0.017.515low
312.2 ± 2.54.311.4 ± 3.81.224.8 ± 15.30.320.11 ± 6.40.40.6 ± 0.019096low
415.4 ± 4.35.511.7 ± 4.61.121.2 ± 7.60.2822.63 ± 12.10.50.82 ± 0.03123130low
517.3 ± 8.16.220.6 ± 9.72.118.2 ± 4.60.2434.25 ± 17.90.70.36 ± 0.15463low
628.2 ± 13.41019.3 ± 8.31.956.7 ± 27.30.7595.7 ± 56.31.21.7 ± 0.7255287moderate
762.8 ± 29.622.441.6 ± 21.44.1125.2 ± 49.61.6723.14 ± 16.10.50.69 ± 0.2103132low
856.1 ± 18.423.237.5 ± 16.23.793 ± 31.91.2467.45 ± 311.30.44 ± 0.26696low
9109.9 ± 37.539.2226.7 ± 84.822.5118 ± 74.11.57186.34 ± 69.53.72.92 ± 1.1438505high
10166.6 ± 79.359.5202.6 ± 96.120.2122.6 ± 32.91.63192.03 ± 80.43.88.57 ± 3.612851370considerable
1145.4 ± 23.716.248 ± 12.44.8113 ± 65.31.5264.67 ± 41.41.31.59 ± 0.8238262moderate
1258.2 ± 25.120.830.3 ± 16.7380.1 ± 56.21.0756.8 ± 11.41.20.46 ± 0.16995low
1349.7 ± 18.617.236.3 ± 29.13.6105.4 ± 83.81.4136.60 ± 9.20.71.01 ± 0.3151175moderate
1433.4 ± 16.811.942.5 ± 19.44.4127 ± 42.21.6936.92 ± 18.50.70.93 ± 0.3139158moderate
1522.2 ± 11.17.924.5 ± 142.468.5 ± 33.30.9188.73 ± 36.21.81.46 ± 0.9219232moderate
1625.5 ± 13.29.127.2 ± 12.12.752.2 ± 12.10.6934.40 ± 17.70.71.51 ± 0.8226240moderate
P Value0.0010.0010.0010.0010.001

The average Cd concentration was 1.53 mg/kg, which was higher than the earth's crust. Except the second station, the concentration of Cd in other stations was higher than the earth's crust (Tables 1 and 4). Cadmium occurrence in the environment is from both natural and anthropogenic sources. Environmental levels are greatly enhanced by the existing industrial operations as Cd is commonly used as a pigment in paint, plastics, ceramics and glass manufacturing companies. Cadmium is highly toxic, producing symptoms such as nausea, vomiting, respiratory difficulties, cramps and loss of consciousness at high doses. Chronic exposure to this metal can lead to anemia, anosmia (loss of sense of smell), cardiovascular diseases, renal problems and hypertension (17).

The average zinc concentration was 94.09, which was higher than the average concentration of the earth's crust, but it was lower in station 2 to 6, 15 and 16 (Tables 1 and 4). This element is essential for growth of humans, animals and plants and is potentially dangerous for biosphere if present in high concentrations. It is often found in limestone. The main sources of pollution are industries and the use of liquid manure, composted materials and agrochemicals, such as fertilizers and pesticides in agriculture (23). Anemia, muscle pain, stroke, blood diseases and even death can be caused by zinc overdoses (17).

The average chromium concentration was 79.63 mg/kg, which was lower than the average of the earth's crust, but at stations 9 and 10 it was higher than the average of the Earth's crust (Tables 1 and 4). The major sources of chromium are textile factories, tanneries, pharmaceuticals and metals. Pigments containing oil compounds and greases also contain some amount of chromium (4). Chromium is considered as an essential trace element for the maintenance of an effective glucose, lipid and protein metabolism. High doses of chromium cause liver and kidney damage and chromate dust, which is carcinogenic (24).

Table 4 shows the result of ecological risk of heavy metals in surface soils of different land uses. The ecological risk of agriculture and livestock land use was moderate and as indicated by the ecological risks of each element (Er), cadmium is responsible for the pollution. The ecological risk of road and dairy farm land uses were low and road- residential land uses (station 9 and 10) demonstrated high and considerable ecological risk where Cd > Pb > Cu > Cr > Zn were sequentially the most responsible elements. In the study of heavy metals (Cu, Cr, Pb, Ni, Cd, Zn, Fe, Mn and Li) for the determination of the ecological risks in Tehran city also demonstrated the high ecological risk at all samples (25).

The calculated potential ecological risk index at the Golestan Province, Iran, indicated that approximately 68% and 5% of the studied samples had medium and high pollution levels, respectively, whereas a moderate and high potential ecological risk covered about 90% of this province (26).

Population growth and modernization increase the contamination of soils and environment; therefore, it is essential to refine the soil and continually monitor the heavy metals. The average concentrations of Pb, Cu, Zn and Cd in surface soils of the study area were higher than their concentrations in the earth's crust indicating the presence of heavy metals in anthropogenic soils. The pollution index revealed that most of the samples were in moderate or not polluted areas, but was very high with considerable ecological risk in residential-road land uses.

Acknowledgements

References

  • 1.

    Guidelines for Ecological Risk Assessment. 1998;63(93):26846-924.

  • 2.

    Szefer P, Ali AA, Ba-Haroon AA, Rajeh AA, Gel̵don J, Nabrzyski M. Distribution and relationships of selected trace metals in molluscs and associated sediments from the Gulf of Aden, Yemen. ENV POLLUT,. 1999;106(3):299-314.

  • 3.

    Thambiran T, Roseanne D. Air pollution and climate change co-benefit opportunities in the road transportation sector in Durban, South Africa. ATMOS ENV. 2011;45(16):2683-9. https://doi.org/10.1016/j.atmosenv.2011.02.059.

  • 4.

    Sayadi MH, Sayyed MRG, Shabani N. Quantification of heavy metal pollutants in the surface soils of Chitgar industrial area Tehran, Iran with spatial references to their spatial pattern. POLLUT RES. 2009;28:345-51.

  • 5.

    Micó C, Recatalá L, Peris M, Sánchez J. Assessing heavy metal sources in agricultural soils of an European Mediterranean area by multivariate analysis. Chemosphere. 2006;65(5):863-72. https://doi.org/10.1016/j.chemosphere.2006.03.016.

  • 6.

    Sayadi MH, Rezaei MR. Impact of land use on the distribution of toxic metals in surface soils in Birjand city, Iran. PROC INT ACAD ECOL ENV SCI. 2014;4(1):18-29.

  • 7.

    Lin C, Chen S, Huang K, Hwang W, Chang-Chien G, Lin W. Characteristics of Metals in Nano/Ultrafine/Fine/Coarse Particles Collected Beside a Heavily Trafficked Road. ENV SCI TECH. 2005;39(21):8113-22. https://doi.org/10.1021/es048182a.

  • 8.

    Sayyed G, Sayadi MH. Variations in the heavy metal accumulations within the surface soils from the Chitgar industrial area of Tehran. PROC INT ACAD ECOL ENV SCI. 2011;1(1):36-46.

  • 9.

    Dao L, Morrison L, Zhang H, Zhang C. Influences of traffic on Pb, Cu and Zn concentrations in roadside soils of an urban park in Dublin, Ireland. ENV GEOCHEM HEALTH. 2014;36(3):333-43. https://doi.org/10.1007/s10653-013-9553-8.

  • 10.

    Manta DS, Angelone M, Bellanca A, Neri R, Sprovieri M. Heavy metals in urban soils: a case study from the city of Palermo (Sicily), Italy. SCI TOTAL ENV. 2002;300(1–3):229-43. https://doi.org/10.1016/S0048-9697(02)00273-5.

  • 11.

    Rodríguez JA, Nanos N, Grau JM, Gil L, López-Arias M. Multiscale analysis of heavy metal contents in Spanish agricultural topsoils. Chemosphere. 2008;70(6):1085-96. https://doi.org/10.1016/j.chemosphere.2007.07.056.

  • 12.

    Mapanda F, Mangwayana EN, Nyamangara J, Giller KE. The effect of long-term irrigation using wastewater on heavy metal contents of soils under vegetables in Harare, Zimbabwe. AGR ECOSYST ENV. 2005;107(2–3):151-65. https://doi.org/10.1016/j.agee.2004.11.005.

  • 13.

    Tiller KG. Urban soil contamination in Australia. SOIL RES. 1992;30(6):937-57. https://doi.org/10.1071/SR9920937.

  • 14.

    Wu S, Zhou S, Li X. Determining the anthropogenic contribution of heavy metal accumulations around a typical industrial town: Xushe, China. J Geochem Explor. 2011;110(2):92-7. https://doi.org/10.1016/j.gexplo.2011.04.002.

  • 15.

    Sayadi MH, Sayyed MRG. Comparative assessment of baseline concentration of the heavy metals in the soils of Tehran (Iran) with the comprisable reference data. ENV Earth Sci. 2011;63(6):1179-88. https://doi.org/10.1007/s12665-010-0792-z.

  • 16.

    Amini M, Afyuni M, Khademi H, Abbaspour KC, Schulin R. Mapping risk of cadmium and lead contamination to human health in soils of Central Iran. Sci Total ENV. 2005;347(1–3):64-77. https://doi.org/10.1016/j.scitotenv.2004.12.015.

  • 17.

    Sayadi M.H, Torabi S. Geochemistry of soil and human health: A Review. Pollution Res. 2009;28(2):257-62.

  • 18.

    Page A, Miller R, Keeney D. Total carbon, organic carbon, and organic matter. Methods Soil Anal. 1982;2:539-79.

  • 19.

    Hakanson L. An ecological risk index for aquatic pollution control.a sedimentological approach. Water Res. 1980;14(8):975-1001. https://doi.org/10.1016/0043-1354(80)90143-8.

  • 20.

    Patel KS, Shrivas K, Hoffmann P, Jakubowski N. A survey of lead pollution in Chhattisgarh State, central India. Env Geochem Health. 2006;28(1-2):11-7. https://doi.org/10.1007/s10653-005-9006-0.

  • 21.

    Srinivasa Gowd S, Govil P. Distribution of heavy metals in surface water of Ranipet industrial area in Tamil Nadu, India. Env Monit Assess. 2008;136(1-3):197-207. https://doi.org/10.1007/s10661-007-9675-5.

  • 22.

    Siegel FR. Environmental Geochemistry of potentially Toxic Metals. 2007.

  • 23.

    Kumar S, Shirke KD, Pawar NJ. GIS-based colour composites and overlays to delineate heavy metal contamination zones in the shallow alluvial aquifers, Ankaleshwar industrial estate, south Gujarat, India. Env Geol. 2008;54(1):117-29. https://doi.org/10.1007/s00254-007-0799-2.

  • 24.

    Krishna AK, Govil PK. Heavy metal contamination of soil around Pali Industrial Area, Rajasthan, India. Env Geol. 2004;47(1):38-44. https://doi.org/10.1007/s00254-004-1124-y.

  • 25.

    Saeedi M, Li LY, Salmanzadeh M. Heavy metals and polycyclic aromatic hydrocarbons: Pollution and ecological risk assessment in street dust of Tehran. J Hazard Mater. 2012;15(227-8):9-17. https://doi.org/10.1016/j.jhazmat.2012.04.047.

  • 26.

    Mirzaei R, Ghorbani H, Hafezi Moghaddas N, Martín JAR. Ecological risk of heavy metal hotspots in topsoils in the Province of Golestan, Iran. J Geochem Explor. 2014;147, Part B:268-76. https://doi.org/10.1016/j.gexplo.2014.06.011.