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International Journal of
eISSN: 2576-4454

Hydrology

Research Article Volume 1 Issue 2

Trace elements levels in drinking water from gokana, Ogoniland, river state, Nigeria

Nkpaa KW, Amadi BA, Wegwu MO

Department of Biochemistry (Environmental Toxicology Unit), University of Port Harcourt, Nigeria

Correspondence: Nkpaa KW, Department of Biochemistry (Environmental Toxicology Unit), University of Port Harcourt, Nigeria

Received: August 12, 2017 | Published: August 30, 2017

Citation: Nkpaa KW, Amadi BA, Wegwu MO. Trace elements levels in drinking water from gokana, ogoniland, river state, nigeria. Int J Hydro. 2017;1(2):55-57. DOI: 10.15406/ijh.2017.01.00010

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Abstract

This study investigated the levels of trace metals in drinking water in crude oil contaminated communities in Gokana, Rivers State, Nigeria. The trace metals levels were measured with atomic absorption spectrophotometer. The levels of Co, Zn, Mg, Cu and Fe in the drinking water ranged between 0.65‒0.93, 0.12−0.52, 0.21‒57, 0.11−0.42, 0.67‒2.20, respectively. The levels of Co, Cu and Fe in drinking water in the study sites analyzed were significant (p˂0.05) higher when compared with their corresponding permissible limits by WHO except magnesium and zinc that were below the permissible limit. Co, Cu and Fe were ranged between 2−8 times larger than the permissible limits. The high level of Co, Cu and Fe render this water from these communities in Gokana unsuitable for human consumption due to their potentials adverse health effect at high levels.

Keywords: Trace metals, Gokana, Drinking water, WHO, Health risks

Introduction

Trace element is one of the common and persistent contaminations aquatic ecosystems due to their resistance to decomposition in natural environment.1 Common source of trace element in the aquatic environment are from agriculture water drainage, bedrocks, discharge of urban and industrial waste water and runoff from riverbank.2,3 Moreover, increase of trace element above permissible limit may also be as a result of natural process or unethical human practices such as crude oil pipeline sabotage as in the case of Gokana, Ogoniland, Rivers State. The health risk of metals in the water body especially drinking water depend mainly on the dose, route of exposure, chemical form, body distribution, storage, bio-availability and excretion parameters.4 Recently, more research work has focused more on investigating the metals in drinking water, seafood and food crops due to the fact that large population size contribute immensely to metals levels, whether the level is low or in excess including chronic poisoning.5,6 It is also important to note that ingestion of water containing significant amounts of heavy metals may cause serious health effects. Trace element levels in ground water (Borehole water) are causing serious health concern because of their adverse effect on human physiological and biochemical functions. Some adverse effect of metals include cancer, renal failure, loss of breath, neuronal damage, skin lesion, hepatocellular toxicity, intravascular hemolysis, hypertension, melanosis, peripheral gastrointestinal bleeding, vascular disease etc.710 among those who are exposed to high dose of trace metals. Trace element levels above the permissible limit of drinking water standards cause great health concern. Release of trace element into the water body may percolates via sub-surface water bodies and get absorbed in the cause of it transportation as a result of various geochemical processes. The presence and mobility of trace element in groundwater body is sustained by absorption processes. Gokana, Rivers State has experience so many incidence of crude oil spill due to pipeline failure, artisanal refining and illegal bunkering,1113 data on trace metals in water bodies of crude contaminated communities are scares. The people in these communities use water from these boreholes for drinking, bathing and cooking on a daily basis without further treatment. Therefore, this study aimed to assess the levels of trace metals in borehole water in some crude oil contaminated communities in Gokana, River State, Nigeria.

Materials and methods

Gokana, Ogoniland, Rivers State heavily polluted by crude oil spill. It is a region in Niger Delta covering some 1000 km2 in the southeast of the Niger Delta basin. It is located at the following geographical coordinate: latitude 4° 40′ 5″ N and 4° 43′ 19.5″ N and longitude 7° 22′ 53.7″ E and 7° 27′ 9.8″ E.11−13 The map of the study area is presented in Figure 1.

Figure 1 Map of the study area.

Sample collection and analysis

Twenty-five water samples were collected from Kpor, Mogho, B-Dere, K-Dere and Bodo City in Gokana, Rivers State, five water samples from each community. People in these communities fetch water from borehole for drinking, washing or cooking without further treatment. The water samples were collected in plastic containers acidified in situ with 10% solution of Nitric acid (HNO3), sealed, labeled and then transported to the laboratory. The water samples were thereafter filtered through 0.45-μm filter membranes. All samples were then stored in sealed polyethylene sample bottles and refrigerated at 4°C until analyzed. Trace metals evaluated in the water samples were: Cobalt (Co), zinc (Zn), magnesium (Mg), copper (Cu) and iron (Fe). The concentrations of elements in the water sample were measured using atomic absorption spectrophotometer (AAS) equipped with graphite furnace (AAnalyst 700 Perkin-Elmer).

Statistical analysis

The data were statistically analyzed by SPSS software version 26. T-Testas applied for evaluating the significant difference between hazardous metals concentration in drinking water from the study sites and established permissible limits.

Results and discussion

The standard permissible limits of trace metals as recommended by the World Health Organization are presented on Table 1. The levels of trace evaluated in this were compared with the permissible to ascertain the health risks via consumption of drinking water from crude contaminated communities in Gokana, Rivers State, Nigeria. The level of Co, Zn, Mg, Cu and Fe in drinking water from the study sites are presented in Table 2. The trace metals analyzed in this study were detected in the water samples in varying concentrations. The levels of Co, Zn, Mg, Cu and Fe in the drinking water ranged between 0.65‒0.93, 0.12−0.52, 0.21‒57, 0.11−0.42, 0.67‒2.20, respectively. The trace metals (Co, Cu and Fe) in drinking water in the study sites analyzed were significant (p˂0.05) difference when compared with their corresponding permissible limits by WHO14 except magnesium and zinc that were below the permissible limit. Co, Cu and Fe were even a 2-8 times larger than the permissible limits. In this study, Co, Cu and Fe exceeded the permissible limit recommended by WHO for drinking water and may not be safe for human consumption. It is evidenced from this study that the quality of water is below standard. The levels of Co, Cu and Fe in drinking water from the study area are higher than the permissible limit established by WHO14 These higher levels of trace metals may lead to detrimental effect on the inhabitant of the study area and as such may not be safe for human consumption. Regulatory bodies may need to step up the monitoring of water body especially drinking water assessment. Penalties also need to be implemented on individuals or companies contributing to environmental degradation. This will drastically reduce the exposure rate of the people in study area to trace metals contamination. There is urgent need to investigate the levels of trace metals in seafood, food crops and borehole on a monthly basis and evaluation of seasonal variations of these trace metals.

Trace metals

Symbols

Permissible limit14

Cobalt

Co

0.05

Zinc

Zn

5

Magnesium

Mg

3

Copper

Cu

0.05

Table 1 Permissible limits of trace elements in drinking water by World Health Organization

Heavy metals

 

 

 

 

 

Sites

Co

Zn

Mg

Cu

Fe

Gbe

0.77±0.02

0.43±0.01

0.57±0.02

0.34±0.01

0.67±0.03

Kpor

0.65±0.03

0.12±0.01

0.33±0.03

0.42±0.01

1.34±0.04

Mogho

0.75±0.02

0.34±0.02

0.64±0.02

0.11±0.01

1.28±0.02

B-Dere

0.93±0.01

0.22±0.02

0.21±0.02

0.31±0.02

1.43±0.03

K-Dere

0.88±0.03

0.32±0.03

0.43±0.01

0.27±0.01

2.20±0.02

Bodo City

0.90±0.02

0.52±0.02

0.22±0.03

0.21±0.01

1.28±0.02

Table 2 Trace metals level (mg/L) in drinking water from Gbe, Kpor, Mogho, B-Dere, K-Dere, and Bodo City, Gokana Local Government Area, Ogoniland, Rivers State, Nigeria

Acknowledgement

None.

Conflict of interest

None.

References

  1. Arnason JG, Fletcher BA. A 40+Year Record of Cd, Hg, Pb, and U Deposition in Sediments of Patroon Reservoir, Albany Country, NY, USA. Environ Pollut. 2003;123(3):383−391.
  2. Soares HMVM, Boaventura RAR, Machado AASC, et al. Sediments as Monitors of Heavy Metal Contamination in the Ave River Basin (Portugal): Multivariate Analysis of Data. Environ Pollut. 1999;105(3):311‒323.
  3. Yang H, Rose N. Trace Element Pollution Records in Some UK Lake Sediments, Their History, Influence Factors and Regional Differences. Environ Int. 2005;31(1):63−75.
  4. Khan TA. Trace Elements in the Drinking Water and Their Possible Health Effects in Aligarh City, India. Journal of Water Resource and Protection. 2011;3:522‒530.
  5. Bunnell JE, Finkelman RB, Centeno JA, et al. Medical Geology: A globally Emerging Discipline. Geologica Acta. 2007;5(3):273−281.
  6. Finkelman RB. Health Impacts of Coal: Facts and Fallacies. Ambio; 2007;36(1):103‒106.
  7. Fatmi Z, Azam I, Ahmed F, et al. Health burden of skin lesions at low arsenic exposure through groundwater in Pakistan. Is river the source?. Environ Res. 2009;109(5):575−581.
  8. Muhammad S, Shah MT, Khan S. Arsenic health risk assessment in drinking water and source apportionment using multivariate statistical techniques in Kohistan region, northern Pakistan. Food Chem Toxicol. 2010;48(10):2855‒2864.
  9. Buchet JP, Lison D. Clues and uncertainties in the risk assessment of arsenic in drinking water. Food Chem Toxicol. 2010;38(1):S81−S85.
  10. Shah MT, Ara J, Muhammad S, et al. Health risk assessment via surface water and sub-surface water consumption in the mafic and ultramafic terrain, regulations and guidelines for risk remediation in North America. J Water Health. 2012;12(3):372‒392.
  11. Nkpaa KW, Wegwu MO, Essien EB. Heavy metals concentrations in four selected seafood from crude oil polluted waters of Ogoniland, Rivers State, Nigeria. Archives of Applied Science Research. 2013;5(4):97−104.
  12. Nkpaa KW, Patrick-Iwuanyanwu KC, Wegwu MO, et al. Health risk assessment of hazardous metals for population via consumption of seafood from Ogoniland, Rivers State, Nigeria; a case study of Kaa, B-Dere, and Bodo City. Environ Monit Assess. 2016;188(1):9.
  13. Nkpaa KW, Onyeso GI, Achugasim O. Heavy metals levels in shellfish from Bodo City and B-Dere, Ogoniland, Rivers State, Nigeria, and evaluation of possible health risks to consumers. Sustainable Water Resources Management. 2017;3(1):83‒91.
  14. WHO. International year of fresh water. General Assembly Resolution A/RES/55/196. 2013.
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