Submit manuscript...
Advances in
eISSN: 2373-6402

Plants & Agriculture Research

Research Article Volume 5 Issue 4

Status of heavy metals in water and sediments of canals and rivers around the Dhaka city of Bangladesh and their subsequent transfer to crops

Md Jamal Uddin,1 Zakia Parveen,2 Md Faruque Hossain3

1Department of Soil Science, Barisal University, Bangladesh
2Department of Soil, Water and Environment, University of Dhaka, Bangladesh
3American International University-Bangladesh, Bangladesh

Correspondence: Md Faruque Hossain, American International University, Kemal Ataturk Avenue, Banani, Dhaka 1213, Bangladesh

Received: August 09, 2016 | Published: December 19, 2016

Citation: Uddin MJ, Parveen Z, Hossain MF. Status of heavy metals in water and sediments of canals and rivers around the Dhaka city of Bangladesh and their subsequent transfer to crops. Adv Plants Agric Res. 2016;5(4):593-601. DOI: 10.15406/apar.2016.05.00189

Download PDF

Abstract

The study was carried out to observe the present status of heavy metals in water, sediment, soil and plant in the Tejgaon-Rampura-Shitalakhya water channel and the adjacent areas of the Dhaka city as well as to evaluate the heavy metal transfer in the water-soil-plant systems. Water, sediment, soil and plant samples were analyzed to know about lead, cadmium, copper and zinc contents. The findings show that heavy metal concentrations in water, sediment, soil and plant in the study area had the trend: Tejgaon Khal>Rampura canal>Shitalakhya river. Different water quality parameters such as pH, DO, BOD, COD, TDS, and NH3 shows that most of the values are higher than the DoE (Bangladesh) recommended irrigation water standards. The heavy metal concentrations in water varies and are well below the recommended values except for Cd and the trend follow the order Pb>Cd>Zn>Cu. The concentrations of the investigated heavy metals in sediment samples are found higher than the USEPA recommended sediment standards and follow the trend Zn>Cu>Pb>Cd. Similar trends are observed for the heavy metals in soil. The accumulation of heavy metals in plants followed the trend Zn>Pb>Cu>Cd in the Tejgaon and Rampura area while the trend are Zn>Cu>Pb>Cd in plants from Shitalakhya. In most of the cases the results of the tested parameters shows significant variations (at 1% level) from Tejgaon river samples with others.

Keywords: wastewater, heavy metals, soil, plant, sediment

Introduction

Waste water disposal is a growing concern in developing countries as large quantities of municipal waste and industrial effluent are being produced due to increased urbanization and industrialization.1 Application of wastewater to cropland could be an alternative source of nutrients because it can improve physical properties and increase nutrient contents of soils;2 e.g., wastewater irrigation provides N, P and organic matter to the soils.3 Nevertheless, there is a risk of potentially toxic elements such as Cd, Pb, Cu, Zn, Fe and Mn accumulation from domestic and industrial sources.4 The occurrence of heavy metals in industrial wastewater is often present at significant levels and if discharged into surface waters can have severe effects on the environment and public health. Therefore, their high concentration in plant tissues brings about poisoning problems in human beings and some other animals feeding on specific plant tissues.1 Trace metal composition of soil varies widely depending on the sources, industrial waste type and geographical location.5

A number of studies are reported on the heavy metal contamination of soil and plants in industrial sites around Dhaka city.6–9 However, these are no extensive and conclusive findings reported. The wastes from various industries contain a variety of heavy metals, organic and inorganic components and the physical quality of this water is very bad and creates various types of diseases with common skin diseases in the nearby localities. Tejgaon Khal receives the industrial as well as domestic wastes from the densely habited industrial site now located in the mid of the capital city of Dhaka. Thus, there is a possibility of the presence of large amount of heavy metals in water of Tejgaon Khal to Shitalakhya River which is the sink of these wastes. The water of Balu River and Shitalakhya River are extensively used for irrigation in the agricultural lands of the associated area which also causes a threat of heavy metal contamination in the agricultural products grown in this region and consequent human health problems. Therefore, this research objective is to identify the level of Cu, Zn, Pb and Cd in water, sediment, soils and vegetables from canal of Tejgaon Khal-Rampura Canal-Shitalakhya River.

Material and methods

To complete the comprehensive study of the proposed research, the study area was selected from Tejgaon-Rampura canal to Shitalakhya River – a span of 30 km (Figure 1). The whole area was divided into three small parts viz., Tejgaon Khal (T), Rampura Khal-Balu River (R) and Shitalakhya River (S) closed to Balu River. Ten points from each part were selected and water, sediment, soil and plant samples were collected from each point. Water samples were collected by using 500 ml plastic bottles; pH and DO were tested instantly. Two sets of water samples were collected from each point: one set was used to determine BOD and COD and the other set was preserved with 2-3 drops of concentrated HCl in refrigerator for further analysis. The collected sediment samples were dried appropriately and then passed through a 0.5 mm sieve. The sieved samples were stored in plastic pots for chemical analysis. The soil samples were collected from the surface 0-15 cm depth, samples were air dried and visible roots and debris were removed and discarded and preserved as described by Imamul Huq and Alam.10

Figure 1 Sampling points of the studied area.

Plant samples were collected from the respective field from where the soil samples were collected. The plant samples were washed first with tap water and then again with deionized distilled water. The fresh weights of collected samples were taken. For chemical analysis, the samples were first air dried and then oven dried at 80ºC ± 5ºC for 48 hours and then dry weight of the plant samples were taken. The samples were ground with an electrical grinder and passed through a 0.2 mm sieve. Various chemical and physico-chemical properties of the water, sediment, soil and plant samples were analyzed in the laboratory as described by Imamul Huq and Alam.10 Results were calculated on oven dry basis. The data are subjected t statistical analysis for pair test using Minitab-16 software.

Results and discussion

Physicochemical characteristics of water

Different water quality parameters like pH, Dissolved oxygen (DO), Biological Oxygen Demand (BOD), Chemical Oxygen Demand (COD), Total Dissolved Solids (TDS), Ammonia-N, along with some heavy metals Zinc (Zn), Copper (Cu), Lead (Pb) and Cadmium (Cd) were analyzed and the results are given in the Table 1. Color and odor are important characteristics of water for physical characterization and it was observed from the study that the color of the water of Tejgaon Khal and Rampura Canal was black or dark black. The pH values of collected water sample ranges from 6.62 to 7.46, which is slightly acidic to slightly alkaline in nature and it increased with increasing distance towards the Tejgaon Khal to Shitalakhya River (Table 1). The pH of Shitalakhya River and Rampura Khal showed significant (at 5% level) difference with Tejgaon Khal. It might be due to higher amount of industrial effluent discharge in Tejgaon Khal.

Point

pH

BOD

COD

DO

TDS

Ammonia

Zn

Cu

Pb

Cd

T1

6.69

650

510

0.29

1131

2.57

0.05

0.032

0.61

0.095

T2

7.46

560

500

0.33

1153

2.56

0.01

0.016

0.53

0.097

T3

7.3

520

480

0.34

1122

2.54

0.2

0.015

0.12

0.13

T4

6.62

490

480

0.35

1110

2.52

0.15

0.014

0.09

0.09

T5

6.82

510

450

0.38

1108

2.55

0.08

0.017

0.16

0.09

T6

7.06

520

420

0.34

1107

2.5

0.1

0.014

0.1

0.13

T7

7.06

490

350

0.37

1106

2.51

0.06

0.016

0.26

0.17

T8

7.06

482

350

0.38

1093

2.56

0.04

0.01

0.32

0.133

T9

7.15

470

450

0.35

1090

2.71

0.12

0.011

0.56

0.13

T10

7.08

520

430

0.33

1158

2.79

0.09

0.008

0.42

0.133

R1

7.1

530

400

0.44

1108

2.66

0.12

0.01

0.6

0.28

R2

6.9

480

300

0.37

1108

2.65

0.15

0.032

0.07

0.17

R3

7.08

480

290

0.33

1105

2.64

BDL*

BDL*

BDL*

0.187

R4

7.21

470

260

0.38

1106

2.65

0.1

0.008

0.001

0.223

R5

7.25

490

240

0.35

1103

2.69

0.15

BDL*

BDL*

0.133

R6

7.32

490

220

0.34

1101

2.67

0.08

0.01

BDL*

0.3

R7

7.32

480

220

0.37

1015

2.68

0.05

BDL*

0.06

0.31

R8

7.32

220

270

1.21

1010

2.37

0.03

0.006

BDL*

0.31

R9

7.3

180

250

1.66

1006

2.25

BDL*

BDL*

BDL*

0.27

R10

7.28

160

230

2.12

982

2.24

0.02

0.01

0.03

0.21

S1

7.32

140

280

2.32

858

2.15

BDL*

BDL*

0.004

0.133

S2

7.22

120

260

2.36

827

2.15

0.01

0.003

BDL*

0.127

S3

7.29

130

170

2.34

821

2.1

BDL*

BDL*

BDL*

0.11

S4

7.31

90

220

2.62

820

1.97

BDL*

BDL*

BDL*

0.12

S5

7.3

110

190

2.69

781

0.53

0.02

0.001

BDL*

0.13

S6

7.31

80

200

2.56

775

0.57

0.008

BDL*

BDL*

0.17

S7

7.3

60

180

2.76

766

0.45

BDL*

BDL*

BDL*

0.15

S8

7.31

50

160

2.74

747

0.46

0.005

0.002

0.001

0.13

S9

7.31

30

150

2.96

744

0.5

0.006

BDL*

0.001

0.15

S10

7.29

30

130

3.08

743

0.52

BDL*

BDL*

BDL*

0.14

Table 1 Physicochemical properties of water sample (mg L-1) collected from the studied area

* BDL = Below Detection Limit

Dissolved oxygen is an important parameter for water quality assessment. The DO at different sampling points ranged from 0.29 to 3.08 mgL-1 and showed an increasing trend from Tejgaon Khal to Shitalakhya River (Figure 2). It might be due to dumping of untreated waste materials from industrial sources of Tejgaon area and these pollution levels became comparatively higher than Rampura Khal and Shitalakhya River. The DO values of Shitalakhya River showed highly significant difference (at 1% level) with the DO values of Tejgaon and Rampura Khal. Rahman and Hadiuzzaman11 also found lower levels of DO in industrially polluted water. It has been noticed that the BOD and COD values of the studied area represented a sharp decreasing trend from the Tejgaon Khal to Shitalakhya River (Figure 2). The values were ranged from 650 to 30mgL-1 for BOD and 510 to 130mgL-1 for COD. The BOD and COD values recorded from Tejgaon and Rampura Khal was higher than the standard value which is 50mgL-1 and 200mgL-1.12 The BOD and COD values of Shitalakhya river was varied significantly (at 1% level) in comparison with the BOD and COD values of Tejgaon and Rampura Khal while Tejgaon and Rampura Khal also showed significant variation for BOD (at 5% level) and COD (at 1% level) values. This might be due to the huge amount of industrial discharge in Tejgaon Khal which contain large amount of organic and inorganic load. Rahman and Hadiuzzaman 11 also found higher levels of BOD and COD in industrially polluted water.





Figure 2 The changing of different physicochemical parameters in water with distances.

Results followed a slight detrimental trend of total TDS at different sampling points, Tejgaon Khal to Shitalakhya River and ranged from 743 to 1158 mgL-1, respectively. The lowest TDS values were found in water of Shitalakhya River and highest value found in Tejgaon and Rampura and the results was varied significantly (at 1% level). Water that contains less than 500 mgL-1 of dissolved solid is generally satisfactory for the domestic use and the other industrial purposes and water containing more than 1000 mg L-1 of DS (dissolved solid) usually contains minerals that give it a distinct taste or make it unsuitable for human consumption,13 whereas DoE12 recommended permissible limit (2100 mg L-1) for irrigation water. The concentration of NH3-N at different sampling points ranges from 2.79 to 0.45 mg L-1 and highest concentration is found in T10 point in Tejgaon Khal. The concentration of ammonia in water sample found to be lower than the standard value 5 mgL-1.12 The ammonia concentration of Shitalakhya River showed a highly significant difference (at 1% level) with Tejgaon and Rampura Khal. It might be due to the Industrial discharge in Tejgaon Khal which contain large amount of organic and inorganic loads. Rampura Khal also showed the higher ammonia concentration which might be due to the closeness to Tejgaon Khal but with distance it was found a sharply decreasing trend (Figure 2).

Heavy metals in wastewater

The results shows that the concentration of heavy metals in different water samples ranges from 0 to 0.20mg L-1 for Zn, 0 to 0.032mg L-1 for Cu, 0 to 0.61mgL-1 for Pb and 0.09 to 0.31mgL-1 for Cd, respectively. The highest concentrations of Zn, Cu Pb and Cd were found in Tejgaon Khal and Rampura Khal. However, the concentrations in Shitalakhya River were found lower than the Tejgaon and Rampura channel. The allowable limit of Zn, Cu, Pb and Cd in irrigation water is 2 mg L-1, 0.2 mg L-1, 5 mg L-1 and 0.01 mg L-1.10 The concentrations of Zn, Cu and Pb in wastewater found lower than the allowable limit although continuous application of this water might increase the concentration of these metals in soil and plant. The concentration of Cd was found very high than the normal level. The trend of Zn, Cu and Pb concentration was found in the study area Tejgaon Khal> Rampura Canal> Shitalakhya River and incase of Cd, it was found Rampura Canal>Tejgoan Khal> Shitalakhya River (Figure 2). The concentrations of Zn, Cu, Pb in Shitalakhya River varied significantly (at 1% level) and Cd showed insignificant result with Tejgaon Khal. Meanwhile, the concentration of Zn, Cd, Pb and Cd in Shitalakhya River varied significantly with the Rampura Khal (Zn, Cd at 1% and Cu, Pb at 5% level of significance). On the contrary, the Zn, Cu concentration at Rampura Khal did not show any significant difference and Pb, Cd varied significantly (at 1% level) with Tejgaon Khal. Blom14 also reported a decrease in metal concentration away from the source point.

Status of heavy metals in sediments

Sediments represent a potential source of contaminants to the overlying water and hence can influence water quality. For the present study, the collected sediment samples were analyzed for pH (Table 2). The lower limit of pH of the sediment was found 6.37 at point-T1 and highest pH 7.39 found at point-S5 (Table 2). The acidic pH at point-T1 in Tejgaon Khal may be due to the acidic discharge of effluent from nearby industrial area as well as a result of high oxidation of organic carbon in this area which produced large volumes of carbon dioxide that dissolved in the water to produce carbonic acid which lowered the pH. Alkaline pH in Shitalakhya River might be due to the deposition of tremendous amount of sediments which might contain much calcium carbonate, magnesium carbonate. On hydrolysis of these calcium carbonate and magnesium carbonate releases OH- ion which contributes alkalinity in sediment. There is a sharp decreasing trend of Zn, Cu, Pb and Cd concentration found from Tejgaon Khal to Shitalakhya River (Figure 3). The maximum concentration of Zn (347.33 mg kg-1), Cu (203 mg kg-1), Pb (120 mg kg-1) and Cd (35.80 mg kg-1) were found in Tejgaon Khal and minimum concentration of Zn (21.67 mg kg-1), Cu (28.90 mg kg-1), Pb (6 mg kg-1) and Cd (0.53 mg kg-1) were found in Shitalakhya River (Table 2). According to USEPA15 guideline, the concentration of Zn, Cu, Pb and Cd in heavily polluted sediment is >200 mg kg-1, >50 mg kg-1, >60 mg kg-1and >6 mg kg-1. This indicated that Tejgaon and Rampura Khal were highly polluted by industrial discharge and the concentrations of heavy metals in Shitalakhya River were found below the standard limit which is far away from the Tejgaon and Rampura Khal. The concentration of Zn, Cu and Pb in sediment sample from Shitalakhya River showed significant difference (at 1% level) with the sediments of Tejgaon Khal and Rampura Khal. The concentration of Cd in sediment sample from Shitalakhya River showed insignificant results with the sediments of Tejgaon Khal and significant results (at 5% level) with the Rampura Khal. Meanwhile, the concentration of Zn, Pb, Cd in Sediment from Rampura Khal showed no significant difference with Tejgaon Khal and Cu showed significant difference (at 5% level).

Point

pH

Zn (mgkg-1)

Cu

Pb

Cd

1

6.37

174.67

170

62

10.37

T2

7.3

174.33

168

41

9.53

T3

7.05

272.33

112

36

10.07

T4

6.42

197

117

31

28.27

T5

6.67

164.67

186

42

8.6

T6

6.79

126

100

28

52.27

T7

6.8

273

203

88

10.23

T8

6.7

347.33

134

78

10.2

T9

6.87

192.33

147

60

11.03

T10

6.79

64.33

198

120

35.8

R1

6.99

28.67

161

53

11.13

R2

6.87

102

147

33

12.37

R3

7.05

176.33

151

64

12.6

R4

7.14

218.33

87

12

10.23

R5

7.1

253.33

92

15

12

R6

7.2

179.33

107

55

10.27

R7

7.2

304.67

92

41

11.4

R8

7.3

286.33

99

22

10.13

R9

7.25

313.33

99

33

12.4

R10

7.3

136.67

86

28

10.97

S1

7.28

69

90

13

10.53

S2

7.14

88.33

81

11

28.07

S3

7.32

57

71

8

4.9

S4

7.3

57.67

101

10

5.5

S5

7.39

45.67

49

6

1.33

S6

7.31

75

50

8

1

S7

7.32

50.67

49.8

9

1.23

S8

7.36

56.67

28.9

7

0.87

S9

7.3

46.33

59.4

8

0.53

S10

7.32

21.67

28.9

6

0.6

Table 2 Status of heavy metals in sediments collected from the studied area

Figure 3 The changing of heavy metal concentrations in sediments with distances.

Status of heavy metals in soil and plant

The collected soil and plant samples from different point were analyzed in the laboratory to see the pH and heavy metals (Zn, Cu, Pb and Cd) concentration (Table 3).

Points

Soil

Plant

pH

Zn

Cu

Pb

Cd

Zn

Cu

Pb

Cd

T1

5.65

95

98

40

0.6

172

14.5

84.5

4

T2

5.71

143

131

51

0.28

378

15.15

71

5.95

T3

5.56

382

82

45

1.4

263

18

66

4.65

T4

5.6

210

81

52

0.84

412.5

45.75

37.5

5.3

T5

5.56

358

82

40

0.72

425

24.75

13

5.4

T6

5.71

395

95

35

0.3

393

30.5

57

4.3

T7

5.55

139

115

50

0.32

253

53.75

25

3.65

T8

5.81

115

122

30

1.24

289

28.55

34

2.95

T9

5.9

508

110

35

0.52

111

23.55

24.5

2.6

T10

5.71

407

118

25

0.92

380

33

61.5

2.8

R1

4.45

255

80

26

0.56

460

43

73

4.1

R2

4.84

87

63

28

0.6

263.5

57.8

18.5

2.95

R3

4.5

67

81

30

0.32

86.5

60.5

16

3.05

R4

5.01

70

74

26

0.28

267

43

29.5

3.2

R5

4.66

67

65

40

0.52

345

28.5

34.5

3.3

R6

4.7

78

57

45

0.48

241.5

33.5

32

4.2

R7

4.5

127

56

39

0.28

179.5

18.55

14

5.4

R8

5.04

115

54

40

0.28

178

23.55

10

2.45

R9

4.4

71

55

30

0.16

149

18.55

6.5

2.6

R10

4.66

75

50

28

0.24

143.5

16.5

3.5

3.05

S1

6.6

64

37

20

0.2

81.5

12.35

3

2.15

S2

6.35

123

35

22

0.24

77

15

3

2.05

S3

6.55

95

36

17

0.16

142.5

24.5

BDL*

2.3

S4

6.08

102

29

15

0.2

112.5

14.45

2.5

2.65

S5

6.24

86

21

17

0.12

217.5

13.5

BDL*

2.05

S6

6.46

111

26

13

0.04

123.5

11.5

1.95

1.85

S7

6.6

62

26

15

0.04

137.5

13.55

BDL*

2.05

S8

6.5

89

20

19

0.08

132

15.15

0.95

1.85

S9

6.55

115

21

16

0.04

123

14.35

BDL*

2.2

S10

6.62

83

26

15

0.04

93.5

15.15

1.05

1.45

Table 3 Status of heavy metals in soil and plant (mg kg-1) collected from the studied area

*BDL = Below Detection Limit.

PH of the soil

The study revealed that the pH of soil samples collected from associated cultivated land of Tejgaon Khal was acidic and Rampura Khal showed more acidic than Tejgaon Khal (Table 3). Shitalakhya River showed slightly acidic pH. The pH of Tejgaon and Rampura soil showed that this area might be polluted with industrial effluent and municipal waste. Lower pH may be due to battery industry, dyeing industry and electrical industry in that area. It also might be due to the genetically formation of soil from acidic parent material in this area.

Heavy metals in soil

The concentrations of Zn, Cu, Pb and Cd ranges from 62 to 508 mg kg-1 for Zn, 20 to 131 mg kg-1 for Cu, 13 to 52 mg kg-1 for Pb and 0.04 to 1.40 mg kg-1 for Cd, respectively (Table 3). The maximum permissible limit of Zn, Cu, Pb and Cd in soil is 64 mg kg-1, 26 mg kg-1, 32 mg kg-1 and <1 mg kg-1, respectively.10 The results showed that soil samples from Tejgaon Khal contain higher concentration of Zn, Cu, Pb and Cd which are several times higher than the permissible limit. The concentrations of metals in soils are found to decrease with distance away from the disposal point Tejgaon (Figure 4). The concentrations of Zn, Cu, Pb and Cd in soils from Shitalakhya River are found below the standard limit. This implies that the soils from Tejgaon Khal and Rampura Khal is contaminated with heavy metals which may comes to the food chain and may cause toxic effect to human health. The concentration of Zn in soil samples from associated area of Shitalakhya river are varies significantly (at 1% level) with the soils of Tejgaon Khal and insignificantly with the soils of Rampura Khal. Cu, Pb and Cd concentrations in soils from Shitalakhya river area significantly different (at 1% level) with the soils of Tejgaon Khal and Rampura Khal area. Soils from Rampura Khal are also significantly differing for Cu (at 1% level), Zn, Cd (at 5% level) and insignificant difference for Pb with the soils of Tejgaon Khal area. Total Cd, Pb, Zn and Cu contents of surface soil in waste water irrigated locations are above the normal ranges of these metals for soils.2,16

Heavy metals in plant

The concentrations of Zn, Cu, Pb and Cd in plant ranges from 460 to 77 mg kg-1 for Zn, 60.50 to 11.50 mgkg-1 for Cu, 84.50 to 0 mg kg-1 for Pb and 5.95 to 1.45 mg kg-1 for Cd, respectively. The critical limit of Zn, Cu, Pb and Cd in plant is 20 mg kg-1, 6 mg kg-1, 2 mg kg-1 and 0.7 mg kg-1.10 The plants grown on Tejgaon River area shows high concentrations of Zn, Cu, Pb and Cd in Rampura and Shitalakhya area, is much higher than the permissible limit (Figure 4). The high concentration of Zn, Cu, Pb and Cd in plant grown on Tejgaon and Rampura Khal area might be due to high concentration of metals in the soil as caused by irrigation with metal contaminated water released from industries. The concentration of Zn in plants grown on Shitalakhya river area varies significantly with the plants grown on Tejgaon Khal (at 1% level) and Rampura Khal (at 5% level) area. The concentrations of Cu, Pb and Cd in plants grown on Shitalakhya river area varies significantly (at 1% level) with the plants grown on Tejgaon Khal and Rampura Khal area. Zn, Cu and Cd in plants grown on Rampura Khal area are insignificantly different with plant samples from Tejgaon Khal area and the concentration of Pb varies significantly (at 1% level). Several studies have indicated that vegetables grown in heavy metals contaminated soils have higher concentrations of heavy metals than those grown in uncontaminated soils.8,17,18 Elevated levels of Cd, Cu, Pb and Zn in plants in industrially polluted area have been demonstrated by other researchers.8,16





Figure 4 The relation between soil and plant based on presence and uptake of heavy metals with distance.

Correlation between Heavy Metals in Soil and Plant

The correlation between soil and plant for all the heavy metals were positive. The results revealed that the relations of soil and plant for Zn and Cu were significant at 5% level (r=0.456 and r=.451) and significant at 1% level for Pb and Cd (r=0.582 and r=0.479). The correlation pattern indicated that the heavy metal concentrations of Zn, Cu, Pb and Cd in plants were associated with the concentration in the soil.

On the other hand, the metal concentrations present in soil and plant were positive but related differently. The relationship of soil Zn and plant Pb and was significant (r=0.461) but not significant for soil Zn and plant Cu and Cd (r=0.080 and r=0.51). Correlation among soil Cu and plant Zn, Pb and Cd were significant at 1% level. For soil Pb, it showed a significant relationship with plant Zn, Cu and Cd (r=0.540, r=0.365 and r=0.814). The concentration of soil Cd were significantly related with plant Zn and Pb (r=0.552 and r=0.617) but not significant with plant Cu (r=0.306). The correlation data showed positive relationship between metals in plant and soil which revealed that the increasing concentrations of heavy metals in soil will increase in the concentrations in plant. As a result plant uptake nutritional elements through the root from the soil.

From the above discussion, an elevated level of heavy metal was found in wastewater collected from the study area. The concentration of Cd in wastewater was found higher than the recommended irrigation standards which may cause serious impacts on soil-plant system. Although the concentrations of Zn, Cu and Pb were low, however the heavy metal contamination of Tejgaon Khal was high than Shitalakhya river. DO content of the water collected from Tejgaon Khal was only 0.29 mgL-1. The value is several times lower than the permissible limit. Meanwhile, the BOD and COD of the tested water were found higher than the DoE recommended irrigation water standards. The heavy metal concentration in the sediments was found in the order Zn>Cu>Pb>Cd. The trend of contamination in the three different riches are Tejgaon Khal>Rampura Canal>Shitalakhya River. The heavy metal concentration in soil followed the similar trend like that of sediment. Plant samples collected insitu revealed that the contaminants present in the environment do enter into them. The accumulation of heavy metals followed the trend Zn>Pb>Cu>Cd in Tejgaon and Rampura while the trend of accumulation in plants from Shitalakhya was Zn>Cu>Pb>Cd. The present study reveals the fact that the effluents discharged from the industries around the study area are not treated before these are released to the environment. The relevant authority needs to take care.

Acknowledgements

None.

Conflict of interest

The author declares no conflict of interest.

References

  1. Alloway BJ, Ayres DC. Chemical principles of environmental pollution. London: Blackie Academic & Professional; 1995. 291 p.
  2. Kibria MG, Islam M, Alamgir M. Influence of waste water irrigation on heavy metal accumulation in soil and plant. International J App and Natural Sci. 2012;1:43–54.
  3. Siebe C, Cifuentes E. Environmental impact of wastewater irrigation in central Mexico. International J Environ Health Res. 1995;5:161–173.
  4. Kiziloglu FM, Turan M, Sahin U, et al. Effects of waste water irrigation on soil and cabbage plant (Brassica olerecea var. capitate cv. Yalova–1) chemical properties. J Plant Nutrition and Soil Sci. 2007;170(1):166–172.
  5. Krogmann U. Effect of season and population density on source separated waste composts. Waste management and Res. 1999;17(2):109–123.
  6. Kashem MA, Singh BR. Heavy metal contamination of soil and vegetation in the vicinity of industries in Bangladesh. Water, Air and Soil Pollut. 1999;115(1):347–361.
  7. Ullah SM, Gerzabek MH, Mondal MN, et al. Heavy metal pollution of soils and water and their transfer into plants in Bangladesh. Paper presented at the 5th International conference on the biogeochemistry at trace elements. Vienna, Austria; 1999. p. 260–261.
  8. Miah MR, Joardar JC, Chowdhury SA, et al. Contribution of diverse industrial wastes to environmental degradation around Dhaka city. Bangladesh J Sci Res. 2010;23(1):13–18.
  9. Hossain F, Chowdhury MTA, Imamul Huq SM. Carbon economy and Heavy metal contamination in two peri–urban areas of Dhaka city in relation to vegetable cultivation practices. Bangladesh J Sci Res. 2011;23(2):103–114.
  10. Imamul Huq SM, Alam MD. A handbook on analysis of soil, plant and water. BACER–DU, Bangladesh: University of Dhaka; 2005. p. 1–246.
  11. Rahman MD, Hadiuzzaman M. Pollution status and trend in water quality of Shitalakhya and Balu River. B. Sc. Thesis. Department of Civil Engineering, Dhaka, Bangladesh: Bangladesh University of Engineering and Technology; 2005. p. 15–57.
  12. DoE (Department of Environment). Environmental quality standards for Bangladesh. Government of Bangladesh: Ministry of Environment and Forest; 2008.
  13. Irshad M, Malik N, Khan T, et al. Effect of solid waste o heavy metal composition of soil and water at Nattiagali–Abbottabad. Department of Environmental Sciences, Abbottabad, Pakistan; COMSTATS Institute of Information Technology; 2011.
  14. Blom HA. Heavy metal contamination of soils around the cities of Østfold county, Norway (In Norwegian). Ph DThesis, Norway Agric Uni; 1986. p. 87–90.
  15. USEPA (United State Environment Protection Agency). Guidelines for water reuse. U.S. EPA, Offices of water and waste water compliance, Washington, USA; 1992. p. 200–247.
  16. Ramesh HL, Murthy VNY. Assessment of heavy metal contamination in green leafy vegetables grown in Bangalore urban district of Karnataka. Adv in Life Sci and Tech. 2012;6:40–51.
  17. Guttormsen GBR, Singh Jeng AS. Cadmium concentration in the vegetables crops grown in sandy soils as affected by Cd levels in fertilizer and soil pH. Fert Res. 1995;41(1):27–32.
  18. Mondol MN, Bhuyian MAR, Noor S, et al. Growth, yield and mineral nutrition of Rice, Wheat and Lettuce grown on heavy metal polluted soils of Bangladesh. J Environ Sci. 2002;8:60–64.
Creative Commons Attribution License

©2016 Uddin, et al. This is an open access article distributed under the terms of the, which permits unrestricted use, distribution, and build upon your work non-commercially.