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1860797550308622336
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INTELEK Repository
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Online Access
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https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072
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2016-07-21 12:18:05
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Restricted Document
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13200
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UniSZA
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1. Uluturhan, E. and Kucuksezgin, F. (2007).Heavy metal contaminants in Red Pandora (Pagellus erythrinus) tissues from the Eastern Aegean Sea, Turkey. Water Research, 41(6): 1185 - 1192. 2. McGeer, J. C., Szebedinszky, C., McDonald, D.G., and Wood, C.M. (2000).Effects of chronic sublethal exposure to waterborne Cu, Cd or Zn in rainbow trout. 1: Iono-regulatory disturbance and metabolic costs. Aquatic Toxicology, 50(3): 231 - 243. 3. Almeida, J. A., Diniz, Y. S., Marques, S. F. G., Faine, L. A., Ribas, B. O., Burneiko, R. C. and Novelli, E. L. B. (2002).The use of the oxidative stress responses as biomarkers in Nile tilapia (Oreochromis niloticus) exposed to in vivo cadmium contamination. Environment International, 27(8): 673 - 679. 4. Xu, Y. J., Liu, X. Z. and Ma, A. J. (2004).Current research on toxicity effect and molecular mechanism of heavy metals on fish. Marine Science, 28(10): 67 - 70. 5. Yilmaz, F., Özdemir, N., Demirak, A. and Tuna, A. L. (2007).Heavy metal levels in two fish species Leuciscus cephalus and Lepomis gibbosus. Food Chemistry, 100(2): 830 - 835. 6. Gratwicke, B. and Speight, M. R. (2005).The relationship between fish species richness, abundance and habitat complexity in a range of shallow tropical marine habitats. Journal of Fish Biology, 66(3): 650 - 667. 7. Jarić, I., Višnjić-Jeftić, Z., Cvijanović, G., Gačić, Z., Jovanović, L., Skorić, S., and Lenhardt, M., (2011).Determination of differential heavy metal and trace element accumulation in liver, gills, intestine and muscle of sterlet (Acipenser ruthenus) from the Danube River in Serbia by ICP-OES. Microchemical Journal, 98(1): 77 - 81. 8. Burger, J. and Gochfeld, M. (2005).Heavy metals in commercial fish in New Jersey. Environmental Research, 99(3): 403 - 412. 9. Chen, Y., Wang, C., and Wang, Z. (2005).Residues and source identification of persistent organic pollutants in farmland soils irrigated by effluents from biological treatment plants. Environment International, 31(6): 778 - 783. 10. Batvari, B. P. D., Kamala-Kannan, S., Shanthi, K., Krishnamoorthy, R., Lee, K. J. and Jayaprakash, M., (2008).Heavy metals in two fish species (Carangoidel malabaricus and Belone stronglurus) from Pulicat Lake, North of Chennai, Southeast Coast of India. Environmental Monitoring and Assessment, 145(1-3): 167 - 175. 11. Low, K. H., Zain, S. M., and Abas, M. R. (2012).Evaluation of microwave-assisted digestion condition for the determination of metals in fish samples by inductively coupled plasma mass spectrometry using experimental designs. International Journal of Environmental Analytical Chemistry, 92(10): 1161 - 1175. 12. Low, K.H., Zain, S.M., and Abas, M.R., 2011.Evaluation of metal concentrations in red tilapia (Oreochromis spp) from three sampling sites in Jelebu, Malaysia using principal component analysis. Food Analytical Methods, 4(3): 276 - 285. 13. Dethloff, G. M. S., C. J. (2000).Condition factor and organo-somatic indices. U.S. Geological Survey,Information & Technology Report, USGS/BRD-2000-2005. 14. Anno, G. H., Young, R. W., Bloom, R. M. and Mercier, J. R (2003).Pose response relationship for acute ionizing radiation lethality. Health Physics, 84: 565 - 575. 15. Fernandes, C., Fontaínhas-Fernandes, A., Cabral, D. and Salgado, M. A. (2008).Heavy metals in water, sediment and tissues of Liza saliens from Esmoriz-Paramos lagoon, Portugal. Environmental Monitoring and Assessment, 136(1-3): 267 - 275. 16. Roméo, M., Siau, Y., Sidoumou, Z., and Gnassia-Barelli, M. (1999).Heavy metal distribution in different fish species from the Mauritania coast. Science of the Total Environment, 232(3): 169 - 175. 17. Begum, A., Mustafa, A. I., Amin, M. N., Chowdhury, T. R., Quraishi, S. B., and Banu, N. (2013).Levels of heavy metals in tissues of shingi fish (Heteropneustes fossilis) from Buriganga River, Bangladesh. Environmental Monitoring and Assessment, 185(7): 5461 - 5469. 18. Mormede, S. and Davies, I. M. (2001). Heavy metal concentrations in commercial deep-sea fish from the rockall trough. Continental Shelf Research, 21(8-10): 899 - 916. 19. Uysal, K., Köse, E., Bülbül, M., Dönmez, M., Erdoǧan, Y., Koyun, M., Ömeroǧlu, Ç., and Özmal, F., (2009).The comparison of heavy metal accumulation ratios of some fish species in Enne Dame Lake (Kütahya/Turkey). Environmental Monitoring and Assessment, 157(1-4): 355 - 362. 20. Shah, A. Q., Kazi, T. G., Arain, M. B., Jamali, M. K., Afridi, H. I., Jalbani, N., Baig, J. A. and Kandhro, G. A. (2009).Accumulation of arsenic in different fresh water fish species - potential contribution to high arsenic intakes. Food Chemistry, 112(2): 520 - 524. 21. Cattell, R. B. (1966).The scree test for the number of factors. Multivariate Behavioral Research, 1(2): 245 - 276. 22. Al-Yousuf, M. H., El-Shahawi, M. S. and Al-Ghais, S. M. (2000).Trace metals in liver, skin and muscle of Lethrinus lentjan fish species in relation to body length and sex. Science of the Total Environment. 256(2-3): 87 - 94. 23. Ministry of Health Malaysia (1995).Malaysian Food Act 1983 and Food Regulation 1985. Kuala Lumpur.
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norman
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13200 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=13200 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal image/jpeg inches 96 96 norman 46 46 765 1428 2016-07-21 12:18:05 1428x765 7509-01-FH02-ESERI-16-06203.jpg UniSZA Private Access Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis Malaysian Journal of Analytical Sciences In the present study, the concentration of Cr, Cd, Cu, Zn, Pb, and As in various tissues of Hemibagrus sp. from two different habitat were determined with microwave assisted digestion-inductively coupled plasma-mass spectrometry. The objective of this research was to determine the differences between wild and cultivated in terms of heavy metal accumulation in muscle, liver and gills tissues. The metals accumulation pattern relating types of tissue and elements as well as fish habitats were revealed by principal component analysis. The results revealed that variation in metal accumulation pattern is strongly dependent on the type of tissues. The results suggested that Cu, Zn, and Pb are highly associated with liver tissue while Cr and As with muscle and gills. The differences in heavy metal accumulation observed between wild and cultivated Hemibagrus sp. were probably due to the differences in their environmental conditions. 20 3 Malaysian Society of Analytical Sciences Malaysian Society of Analytical Sciences 517-524 1. Uluturhan, E. and Kucuksezgin, F. (2007).Heavy metal contaminants in Red Pandora (Pagellus erythrinus) tissues from the Eastern Aegean Sea, Turkey. Water Research, 41(6): 1185 - 1192. 2. McGeer, J. C., Szebedinszky, C., McDonald, D.G., and Wood, C.M. (2000).Effects of chronic sublethal exposure to waterborne Cu, Cd or Zn in rainbow trout. 1: Iono-regulatory disturbance and metabolic costs. Aquatic Toxicology, 50(3): 231 - 243. 3. Almeida, J. A., Diniz, Y. S., Marques, S. F. G., Faine, L. A., Ribas, B. O., Burneiko, R. C. and Novelli, E. L. B. (2002).The use of the oxidative stress responses as biomarkers in Nile tilapia (Oreochromis niloticus) exposed to in vivo cadmium contamination. Environment International, 27(8): 673 - 679. 4. Xu, Y. J., Liu, X. Z. and Ma, A. J. (2004).Current research on toxicity effect and molecular mechanism of heavy metals on fish. Marine Science, 28(10): 67 - 70. 5. Yilmaz, F., Özdemir, N., Demirak, A. and Tuna, A. L. (2007).Heavy metal levels in two fish species Leuciscus cephalus and Lepomis gibbosus. Food Chemistry, 100(2): 830 - 835. 6. Gratwicke, B. and Speight, M. R. (2005).The relationship between fish species richness, abundance and habitat complexity in a range of shallow tropical marine habitats. Journal of Fish Biology, 66(3): 650 - 667. 7. Jarić, I., Višnjić-Jeftić, Z., Cvijanović, G., Gačić, Z., Jovanović, L., Skorić, S., and Lenhardt, M., (2011).Determination of differential heavy metal and trace element accumulation in liver, gills, intestine and muscle of sterlet (Acipenser ruthenus) from the Danube River in Serbia by ICP-OES. Microchemical Journal, 98(1): 77 - 81. 8. Burger, J. and Gochfeld, M. (2005).Heavy metals in commercial fish in New Jersey. Environmental Research, 99(3): 403 - 412. 9. Chen, Y., Wang, C., and Wang, Z. (2005).Residues and source identification of persistent organic pollutants in farmland soils irrigated by effluents from biological treatment plants. Environment International, 31(6): 778 - 783. 10. Batvari, B. P. D., Kamala-Kannan, S., Shanthi, K., Krishnamoorthy, R., Lee, K. J. and Jayaprakash, M., (2008).Heavy metals in two fish species (Carangoidel malabaricus and Belone stronglurus) from Pulicat Lake, North of Chennai, Southeast Coast of India. Environmental Monitoring and Assessment, 145(1-3): 167 - 175. 11. Low, K. H., Zain, S. M., and Abas, M. R. (2012).Evaluation of microwave-assisted digestion condition for the determination of metals in fish samples by inductively coupled plasma mass spectrometry using experimental designs. International Journal of Environmental Analytical Chemistry, 92(10): 1161 - 1175. 12. Low, K.H., Zain, S.M., and Abas, M.R., 2011.Evaluation of metal concentrations in red tilapia (Oreochromis spp) from three sampling sites in Jelebu, Malaysia using principal component analysis. Food Analytical Methods, 4(3): 276 - 285. 13. Dethloff, G. M. S., C. J. (2000).Condition factor and organo-somatic indices. U.S. Geological Survey,Information & Technology Report, USGS/BRD-2000-2005. 14. Anno, G. H., Young, R. W., Bloom, R. M. and Mercier, J. R (2003).Pose response relationship for acute ionizing radiation lethality. Health Physics, 84: 565 - 575. 15. Fernandes, C., Fontaínhas-Fernandes, A., Cabral, D. and Salgado, M. A. (2008).Heavy metals in water, sediment and tissues of Liza saliens from Esmoriz-Paramos lagoon, Portugal. Environmental Monitoring and Assessment, 136(1-3): 267 - 275. 16. Roméo, M., Siau, Y., Sidoumou, Z., and Gnassia-Barelli, M. (1999).Heavy metal distribution in different fish species from the Mauritania coast. Science of the Total Environment, 232(3): 169 - 175. 17. Begum, A., Mustafa, A. I., Amin, M. N., Chowdhury, T. R., Quraishi, S. B., and Banu, N. (2013).Levels of heavy metals in tissues of shingi fish (Heteropneustes fossilis) from Buriganga River, Bangladesh. Environmental Monitoring and Assessment, 185(7): 5461 - 5469. 18. Mormede, S. and Davies, I. M. (2001). Heavy metal concentrations in commercial deep-sea fish from the rockall trough. Continental Shelf Research, 21(8-10): 899 - 916. 19. Uysal, K., Köse, E., Bülbül, M., Dönmez, M., Erdoǧan, Y., Koyun, M., Ömeroǧlu, Ç., and Özmal, F., (2009).The comparison of heavy metal accumulation ratios of some fish species in Enne Dame Lake (Kütahya/Turkey). Environmental Monitoring and Assessment, 157(1-4): 355 - 362. 20. Shah, A. Q., Kazi, T. G., Arain, M. B., Jamali, M. K., Afridi, H. I., Jalbani, N., Baig, J. A. and Kandhro, G. A. (2009).Accumulation of arsenic in different fresh water fish species - potential contribution to high arsenic intakes. Food Chemistry, 112(2): 520 - 524. 21. Cattell, R. B. (1966).The scree test for the number of factors. Multivariate Behavioral Research, 1(2): 245 - 276. 22. Al-Yousuf, M. H., El-Shahawi, M. S. and Al-Ghais, S. M. (2000).Trace metals in liver, skin and muscle of Lethrinus lentjan fish species in relation to body length and sex. Science of the Total Environment. 256(2-3): 87 - 94. 23. Ministry of Health Malaysia (1995).Malaysian Food Act 1983 and Food Regulation 1985. Kuala Lumpur.
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| spellingShingle |
Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis
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| summary |
In the present study, the concentration of Cr, Cd, Cu, Zn, Pb, and As in various tissues of Hemibagrus sp. from two different habitat were determined with microwave assisted digestion-inductively coupled plasma-mass spectrometry. The objective of this research was to determine the differences between wild and cultivated in terms of heavy metal accumulation in muscle, liver and gills tissues. The metals accumulation pattern relating types of tissue and elements as well as fish habitats were revealed by principal component analysis. The results revealed that variation in metal accumulation pattern is strongly dependent on the type of tissues. The results suggested that Cu, Zn, and Pb are highly associated with liver tissue while Cr and As with muscle and gills. The differences in heavy metal accumulation observed between wild and cultivated Hemibagrus sp. were probably due to the differences in their environmental conditions.
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| title |
Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis
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| title_full |
Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis
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| title_fullStr |
Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis
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| title_full_unstemmed |
Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis
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| title_short |
Evaluation of heavy metal concentrations in wild and cultivated Hemibagrus sp. using principal component analysis
|
| title_sort |
evaluation of heavy metal concentrations in wild and cultivated hemibagrus sp. using principal component analysis
|