Analysis of Heavy Metals in Water and Surface Sediment in Five Rift Valley Lakes in Kenya for Assessment of Recent Increase in Anthropogenic Activities

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Abstract

The concentrations of heavy metals Ag, Cd, Co, Cr, Cu, Mn, Ni, Pb, Sn and Zn were analysed in water and surface sediments of five Rift Valley lakes Nakuru, Elementaita, Naivasha, Bogoria and Baringo in Kenya. The dissolved mean concentration levels (μg/L) in water ranged within 13.0–185.0 (Ag), 2.0–43.0 (Cd), 5.0–316.0 (Co), 25.0–188.0 (Cr), 4.7–100.0 (Cu), 50.0–282.0 (Mn), 19.0–288.0 (Ni), 25.0–563.0 (Pb), 300.0–1050.0 (Sn) and 29.0–235.0 (Zn). The mean sediment concentrations (in μg/g (dry weight)) ranged within 0.1–0.35 (Ag), 0.05–1.18 (Cd), 0.17–1.38 (Co), 1.94–4.91 (Cr), 1.46–20.95 (Cu), 667.7–3946.8 (Mn), 11.69–39.72 (Ni), 10.92–38.98 (Pb), 17.21–56.52 (Sn) and 96.2–229.6 (Zn). The data indicate that some of the sites analysed, especially in Lake Nakuru, had relatively higher concentration levels of heavy metals Cd, Co, Cu, Pb, Ni, and Zn in the water which points to anthropogenic addition. However, potential influence of geochemical processes on the concentration levels in sediment is also shown in Co, Ni, and Cu which were more concentrated in the remote Lake Baringo sediment as well as in Pb and Mn which were more concentrated in the remote Lake Bogoria sediment. Data on some important limnological parameters including pH, salinity, electrical conductivity and temperature are also presented.

Keywords

Heavy metals Rift Valley lakes Kenya 
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Notes

Acknowledgments

We thank the Kenya Marine Fisheries Research Institute (KMFRI) in Mombasa for assistance given to E.Z. Ochieng.

References

  1. Berg H, Kiibus M, Kautsky N (1995) Heavy metals in tropical Lake Kariba, Zimbabwe. Water Air Soil Pollut 82:1–16Google Scholar
  2. Borg H, Jonsson P (1996) Large-scale metal distribution in Baltic Sea sediments. Mar Pollut Bull 32:8–21CrossRefGoogle Scholar
  3. Bowmer CT, Jenner HA, Foekema E, Van der Meer M (1994) The detection of chronic biological effects in the marine intertidal bivalve Cerastoderma edule in model ecosystem studies with pulverized fuel ash: reproduction and histopathology. Environ Pollut 85:191–204CrossRefGoogle Scholar
  4. Burrel DC (1974) Atomic spectrometric analysis of heavy metal pollutants in water. Ann Arbor Science Publishers, London, pp 19–29Google Scholar
  5. Chan KM (1995a) Concentrations of copper, zinc, cadmium, and lead in Rabbit fish (Siganus oramin) collected in Victoria Harbour, Hong Kong. Mar Pollut Bull 31:277–280Google Scholar
  6. Chan KM (1995b) Metallothionein: potential biomarker for monitoring heavy metal pollution in fish around Hong Kong. Mar Pollut Bull 3:411–415Google Scholar
  7. Cheevaporn V, Jacinto GS, San Diego-McGlone (1995) Heavy metal fluxes in Bang Pakong River Estuary, Thailand: sedimentary versus diffusive fluxes. Mar Pollut Bull 31:290–294Google Scholar
  8. Demirak A, Yilma ZF, Tuna AL, Ozdemir N (2006) Heavy metals in water, sediment and tissues of Leuciscus cephalus from a stream in south western Turkey. Chemosphere 63(9):1451–1458CrossRefGoogle Scholar
  9. Everaarts JM, Nieuwenhuize J (1995) Heavy metals in surface sediments and epibenthic macroinvertebrates from the coastal zone and continental slope of Kenya. Mar Pollut Bull 31:281–289CrossRefGoogle Scholar
  10. George GG, Pirie BJ (1984) Interspecies differences in heavy metal detoxication in Oyster. Mar Environ Res 14:462–464CrossRefGoogle Scholar
  11. Gold-Bouchon G, Sima-Alvarez R, Zapata-Perez O, Guemez-Ricalde J (1995) Histopathological effects of petroleum hydrocarbons and heavy metals on the American Oyster (Crassostrea virginica) from Tabasco, Mexico. Mar Pollut Bull 31:439–445CrossRefGoogle Scholar
  12. Hodson PV (1981) Factors affecting the sublethal toxicity of Lead to fish. Mar Pollut Bull 11:241–247Google Scholar
  13. Howarth RS, Sprague JB (1978) Copper lethality to rainbow trout in waters of various hardness and pH. Water Res 21:455–462CrossRefGoogle Scholar
  14. Jeon BH, Dempsey BA, Burgos WD, Royer RA (2003) Sorption kinetics of Fe(II), Zn(II), Co(II), Ni(II), Cd(II), and Fe(II)/Me(II) onto hermatite. Water Res 37:4135–4142CrossRefGoogle Scholar
  15. Lim PE, Lee CK, Din Z (1995) Accumulation of heavy metals by cultured oysters from Merbok Estuary, Malaysia. Mar Pollut Bull 31:420–423CrossRefGoogle Scholar
  16. Ma M, Zhu W, Wang Z, Witkamp GJ (2003) Accumulation, assimilation and growth inhibition of Copper on a freshwater alga (Scenedesmus suspicatus) 86.81 BAG in the presence of EDTA and fulvic acid. Aquat Toxicol 63:221–228CrossRefGoogle Scholar
  17. Ochieng EZ (1987) Limnological aspects and trace elements analysis of some selected Kenyan natural inland waters, MSc Thesis, Department of Chemistry, University of NairobiGoogle Scholar
  18. Onyari JM, Wandiga SO (1989) Distribution of Cr, Pb, Cd, Fe and Mn in Lake Victoria sediments, East Africa. Bull Environ Contam Toxicol 42:807–813CrossRefGoogle Scholar
  19. Schmitt D, Saravia F, Frimmel FH, Schuessler W (2003) NOM-facilitated transport of metal ions in aquifers: importance of complex-dissociation kinetics and colloid formation. Water Res 37:3541–3550CrossRefGoogle Scholar
  20. Wandiga SO, Molepo JM, Alala N (1983) Concentration of heavy metals in water, sediments and plants of Kenyan lakes. Kenya J Sci Technol (Ser A) 4:89–94Google Scholar
  21. Wong CK, Cheung JKY, Chu KH (1995) Effects of Copper on survival, development and growth of Metapenaeus ensis Larvae and Postlarvae (Decapoda:Penaeidae). Mar Pollut Bull 31:416–419CrossRefGoogle Scholar

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© Springer Science+Business Media, LLC 2007

Authors and Affiliations

  1. 1.Department of ChemistryCollege of Biological and Physical Sciences, University of NairobiNairobiKenya
  2. 2.Department of ChemistryMaseno UniversityMasenoKenya

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