Sains Malaysiana 47(6)(2018): 1277–1283

http://dx.doi.org/10.17576/jsm-2018-4706-24

 

Analysis of Heavy Metal Accumulation in Fish in the Terengganu Coastal Area, Malaysia

(Analisis Pengumpulan Logam Berat dalam Ikan di Kawasan Pantai Terengganu, Malaysia)

 

M.N.R. ROSLI1*, S.B. SAMAT1, M.S. YASIR1 & M.F.M. YUSOF2

 

1School of Applied Physics, Faculty of Science and Technology, Universiti Kebangsaan Malaysia

43600 UKM Bangi, Selangor Darul Ehsan, Malaysia

 

2School of Health Sciences, Health Campus, Universiti Sains Malaysia, 16150 Kubang Kerian, Kelantan Darul Naim, Malaysia

 

Received: 25 September 2017/Accepted: 21 January 2018

 

 

ABSTRACT

Bioaccumulation of toxic metals in fish causes serious threats to the human when they are consumed. Thus, the detection of toxic element concentration levels in aquatic component is important. The accumulation of some heavy metals such as Cd, Cu, Fe, Mn, Pb and Zn in fish were determined. Ten species (Selaroides leptolepis, Decapterus maraudsi, Epinephelus lanceolatus, Priacanthus tayenus, Rastrelliger, Megalaspis cordyla, Nibea soldado, Pristipomoides filamentosus, Bramidae and Siganus canaliculatus) were collected from Terengganu coastal area, Malaysia. The analysis was done using inductive coupled plasma-mass spectrometer (ICP-MS) technique. In general, the concentration levels of heavy metals in fish samples are lower than the previous study in various locations. The highest average level of heavy metal recorded in fish is Fe followed by Zn, Mn, Cu, Cd and Pb. The metal concentration found in this study was lower than the national and international recommended dietary allowance (RDA) for human consumption except Fe (52.33 × 10-2 ± 6.39 × 10-2 mg kg-1) which exceeded the limit of 0.3 mg kg-1. Long term monitoring system of metal bioaccumulation in fishes need to be done to provide useful information for the assessment of the potential health risks of metals in Malaysia.

 

Keywords: Bioaccumulation; inductive coupled plasma-mass spectrometry (ICP-MS); recommended dietary allowance (RDA); heavy metals; Terengganu coastal area, Malaysia

 

ABSTRAK

Biotumpukan logam toksik dalam ikan telah menyebabkan ancaman serius kepada manusia apabila ia dimakan. Oleh itu, pengesanan tahap kepekatan unsur toksik dalam komponen akuatik adalah penting. Pengumpulan beberapa logam berat seperti Cd, Cu, Fe, Mn, Pb dan Zn dalam ikan telah ditentukan. Sepuluh spesies (Selaroides leptolepis, Decapterus maraudsi, Epinephelus lanceolatus, Priacanthus tayenus, Rastrelliger, Megalaspis cordyla, Nibea soldado, Pristipomoides filamentosus, Bramidae dan Siganus canaliculatus) dikumpulkan dari kawasan pantai Terengganu, Malaysia. Analisis dilakukan dengan menggunakan spektrometri jisim-plasma gandingan teraruh (ICP-MS). Secara amnya, tahap kepekatan logam berat dalam sampel ikan lebih rendah daripada kajian terdahulu di pelbagai lokasi. Tahap purata tertinggi logam berat yang direkodkan dalam ikan adalah Fe diikuti oleh Zn, Mn, Cu, Cd dan Pb. Kepekatan logam yang terdapat dalam kajian ini adalah lebih rendah daripada elaun pemakanan yang disyorkan (RDA) oleh badan tempatan dan antarabangsa untuk kegunaan manusia kecuali Fe (52.33 × 10-2 ± 6.39 × 10-2 mg kg-1) yang melebihi had 0.3 mg kg-1. Sistem pengawasan jangka panjang biotumpukan logam dalam ikan perlu dijalankan untuk memberikan maklumat berguna untuk menilai potensi risiko kesihatan berkaitan logam di Malaysia.

 

Kata kunci: Biotumpukan; elaun pemakanan yang disyorkan (RDA); kawasan pantai Terengganu, Malaysia; logam berat; spektrometri jisim-plasma gandingan teraruh (ICP-MS)

REFERENCES

Agusa, T., Kunita, A., Sudaryanto, T., Monirith, S.K., Klap, A. & Iwata, H. 2007. Exposure assessment for trace elements from consumption of marine fish in Southeast Asia. Environmental Pollution 145: 266-277.

Agusa, T., Kunito, T., Yasunaga, G., Iwata, H., Subramanian, A., Ismail, A. & Tnabe, S. 2005. Concentrations of trace elements in marine fish and its risk assessment in Malaysia. Marine Pollution Bulletin 51: 896-911.

Basha, P.S. & Rani, A.U. 2003. Cadmium induced antioxidant defense mechanism in freshwater teleost Oreochromis mossambicus (Tilapia). Ecotoxicology and Environmental Safety 56: 218-221.

Bashir, F.H., Othman, M.S., Mazlan, A.G., Rahim, S.M. & Simon, K.D. 2013. Heavy metal concentration in fishes from the coastal waters of Kapar and Mersing, Malaysia. Turkish Journal of Fisheries and Aquatic Sciences 13: 375-382.

Burger, J., Gaines, K.F., Shane Boring, C., Stephens, W.L., Snodgrass, J. & Dixon, C. 2002. Metal levels in fish from the Savannah River: Potential hazards to fish and other receptors. Environmental Research 89: 85-97.

Canli, M. & Atli, G. 2003. The relationships between heavy metal (Cd, Cr, Cu, Fe, Pb and Zn) levels and the size of six Mediterranean fish species. Environment Pollution 121: 129-136.

Dimari, G.A., Abdulkarim, F.I., Akan, J.C. & Garba, S.T. 2008. Metal concentrations in tissues of Tilapia galier, Clarias lazera, and Osteoglosidae caught from Ala Dam, Maiduguri, Borno State, Nigeria. American Journal of Environmental Sciences 4(4): 473-479.

Davison, A.G., Fayers, P.M., Taylor, A.J., Venables, K.M., Darbyshire, J. & Pickering, C.A. 1988. Cadmium fume inhalation and emphysema. The Lancet 1(8587): 663-667.

Dirilgen, N. 2001. Accumulation of heavy metals in freshwater organisms: Assessment of toxic interactions. Turkish Journal of Chemistry 25: 173-179.

Eisler, R. 1998. Copper hazards to fish, wildlife and invertebrates: A synoptic review. Biological Science Report 33: 100-109.

Ekong, E.B., Jaar, B.G. & Weaver, V.M. 2006. Lead-related nephrotoxicity: A review of the epidemiological evidence. Kidney International 70: 2074-2084.

El-sherif, M.S., Ahmed, M.T., El-Danasoury, M.A. & El-Nwishy, N.H.K. 2009. Effects of pollutants on some aquatic organisms in Temsah Lake in Egypt. Journal of Fisheries and Aquatic Sciences 4: 150-160.

Erdoĝrul, Z. & Ates, D.A. 2006. Determination of cadmium and copper in fish samples from Sir and Menzelet dam lake Kahramanmaras, Turkey. Environmental Monitoring Assessment 117: 281-290.

FAO/WHO. 1984. List of Maximum Levels Recommended for Contaminants by the Joint FAO/WHO Codex Alimentarius Commission. Second Series. CAC/FAL, 1-8. Rome: Food and Agriculture Organization of the United Nations.

Finch, C.A. & Huebers, H.A. 1982. Perspective in iron metabolism. National English Journal of Medicine 306: 1520-1528.

Forstner, U. & Wittmann GTW. 1979. Metal Pollution in Aquatic Environment. Berlin: Springer-Verlag.

FSA. 2008. Total Diet Study of Metals and Other Elements. Committee on Toxicity of Chemicals in Food, Consumer Products and the Environment. tox/2008/29, December. United Kingdom.

Ganbi, H.A.A. 2010. Heavy metals pollution level in marine Hammour fish and the effect of popular cooking methods and freezing process on these pollutants. World Journal of Daily Food Sciences 5(2): 119-127.

Gu, Y.G., Lin, Q., Huang, H.H., Wang, L.G., Ning, J.J. & Du, F.Y. 2016. Heavy metals in fish tissues/stomach contents in four marine wild commercially valuable fish species from the western continental shelf of South China Sea. Marine Pollution Bulletin 114(2): 1125-1129.

Hajeb, P., Jinap, S., Ismail, A., Fatimah, A.B., Jamilah, J. & Rahim, M.A. 2009. Assessment of mercury level in commonly consumed marine fishes in Malaysia. Food Control 20(1): 79-84.

Kamaruzzaman, B.Y., Rina, Z., Akbar John, B. & Jalal, K.C.A. 2011. Heavy metal accumulation in commercially important fishes of South West Malaysian coast. Research Journal of Environmental Sciences 5: 595-602.

Kaur, M., Sharma, J.K., Gill, J.P., Aulakh, R.S., Bedi, J.S. & Joia, B.S. 2008. Determination of organochlorine pesticide residue in freshwater fish species in Punjab, India. Bulletin Environmental Contamination Toxicology 80: 154-157.

Lakshmanan, R., Kesavan, K., Vijaya, P., Rajaram, V. & Rajagopal, S. 2009. Heavy metals accumulation in five commercially important fishes of parangipettai, southeast coast of India. Advance Journal of Food Sciences and Technology 1: 63-65.

Liu, J.L., Xu, X.R. & Ding, Z.H. 2015. Heavy metals in wild marine fish from South China Sea: Levels, tissue and species-specific accumulation and potential risk to humans. Ecotoxicology 24: 1583-1592.

Luoma, S.N. & Rainbow, P.R. 2008. Metal Concentration in Aquatic Environment: Science and Lateral Management. Cambridge: Cambridge University Press. 7: 129-141.

Malaysian Food Act and Regulations. 1985. Malaysian Law on Food and Drugs. Kuala Lumpur: Malaysia Law Publisher.

Matta, J., Miled, M., Manger, R. & Tosteson, T. 1999. Heavy metals, lipid peroxidation and cigatcratoxicity in the liver of the Carbben barracula (Sphyrrena barracuba). Biological Trace Element Research 70: 69-70.

Moberg, F. & Folke, C. 1999. Ecological goods and services of coral reef ecosystems. Ecological Economics 29: 215-233.

NAS. 1989. Recommended Dietary Allowances. Subcommittee on the Tenth Edition of the RDAs.National Academy Press

Puel, D., Zsueager, N. & Breittmayer, N.P. 1987. Statistical assessment of a sampling pattern for evaluation of changes in Hg and Zn concentration in Patellacoerulea. Bulletin Environmental Contamination Toxicology 38: 700-706.

Renata, J.M., Lisia Maria, G.D.S. & Aline, S.F. 2012. Determination of inorganic trace elements in edible marine fish from Rio de Janeiro State, Brazil. Food Control 23: 535-541.

Scherz, H. & Kirchhoff, E. 2006. Trace elements in foods: Zinc contents of raw foods - a comparison of data originating from different geographical regions of the world. Journal of Food Composition and Analysis 19: 420-433.

Sivaperumal, P., Sankar, T.V. & Nair, P.G.V. 2007. Heavy metal concentrations in fish, shellfish and fish products from internal markets of India vis-à-vis international standards. Food Chemistry 102: 612-620.

Stancheva, M., Makedonski, L. & Peycheva, K. 2013. Determination of heavy metal concentrations of most consumed fish species from Bulgarian Black Sea Coast. Bulgarian Chemical Communications 46: 195-203.

Türkmen, M., Türkmen, A., Tepe, Y., Töre, Y. & Ates, A. 2009. Determination of metals in fish species from Aegean and Mediterranean Seas. Food Chemistry 113: 233-237.

Tüzen, M. 2003. Determination of heavy metals in fish samples of the middle Black Sea (Turkey) by graphite furnace atomic absorption spectrometry. Food Chemistry 80(1): 119-123.

USFDA. 1993. Guidance Document of Chromium, Arsenic and Nickel in Shellfish. Washington, DC: Center for Food Safety and Applied Nutrition.

Velez, D. & Montoro, R. 1988. Arsenic speciation in manufactured seafood products: A review. Journal of Food Protection 61: 1240-1245.

Vutukuru, S.S. 2005. Acute effects of hexavalent chromium on survival, oxygen consumption, haematological parameters and some biochemical profiles of the Indian major carp, Labeo rohita. International Journal of Environmental Research Public Health 2: 456-462.

Wyse, E.J., Azemard, S. & Mora, S.J. 2003. Report on the world-wide intercomparison exercise for the determination of trace elements and methylmercury in fish homogenate IAEA-404. IAEA Marine Environment Laboratory.

Yasir, M.S., Abd Majid, A., Ahmad Kabir, N. & Yahya, R. 2008. Kandungan logam berat dan radionuklid tabii dalam ikan, air, tumbuhan dan sedimen di bekas tapak lombong. The Malaysian Journal of Analytical Sciences 12(1): 172-178.

Yilmaz, A.B. 2003. Levels of heavy metals (Fe, Cu, Ni, Cr, Pb and Zn) in tissue of Mugil cephalus and Trachurus mediterraneus from Iskenderun Bay. Turkish Environmental Research 92: 277-281.

Zhu, C.Q., Qin, Y., Meng, Q.S., Wang, X.Z. & Wang, R. 2014. Formation and sedimentary evolution characteristics of Yongshu Atoll in the South China Sea Islands. Ocean Engineering 84: 61-66.

 

*Corresponding author; email: racd919@gmail.com

 

 

 
previous