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1860797423745499136
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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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| date |
2015-12-30 16:09:09
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Restricted Document
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12659
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UniSZA
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1. Hogan, M.C. (2014). Bacteria. Available at: http://www.eoearth.org/view/article/150368/. Accessed November 2014. 2. Ragini, G. and Pankaj, B. (2012). Cynobacteria: A comprehensive review. International Research Journal of Pharmacy 3(2): 1-5. 3. Mandal, A. K., Sarma, P. M., Singh, B., Jeyaseelan, C. P. Channashettar, V. A. Lal, B. and Datta, J. (2012) Bioremediation: An Environment Friendly Sustainable Biotechnological Solution for Remediation of Petroleum Hydrocarbon Contaminated Waste. ARPN Journal of Science and Technology 2: 1-12. 4. Alavijeh, P. K., Halimoon, N., Pauzi, Z., Johari, W. L. W., Karimi, B. (2014). Crude oil biodegradation using isolated bacteria from polluted soil: pp 127-129. 5. Naik, M. M., Pandey, A. and Dubey, S. K (2012). Bioremediation of Metals Mediated by Marine Bacteria. Microorganisms in Environmental Management Microbes and Environment: pp 665-682. 6. Sharma, S. (2012). Bioremediation: Features, Strategies and applications. Asian Journal of Pharmacy and Life Science 2 (2): 1-12. 7. Hamza, U. D., Mohammed, I. A. and Sale, A. (2012). Potentials of bacterial isolates in bioremediation of petroleum refinery wastewater. Journal of Applied Phytotechnology in Environmental Sanitation 1(3):131-138. 8. Poornima, K., Karthik, L., Swadhini, S. P., Mythili, S., and Sathiavelu, A. (2010). Degradation of Chromium by Using a Novel Strains of Pseudomonas Species. Journal of Microbial and Biochemical Technology, 2: 95- 99. 9. Igeno, I.M., Orovengua, E., Guijo, I.M., Merchán, F., Quesada and Blasco, R. (2007). Biodegradation of cyanide-containing wastes by Pseudomonas pseudoalcaligenes CECT5344. Available at: http://www.formatex.org/microbio/pdf/Pages100-107.pdf. Accessed March, 2015. 10. Vidali, M. (2001). Bioremediation. An overview. Available at: http://www.eolss.net/sample-chapters/c17/e6- 58-09-13.pdf. Accessed March 2015. 11. Salem, I. B., Sghaier, H., Trifi1, H., Héni, S., Khwaldia, K., Saidi, M. and Landoulsi, A. (2012). Isolation and characterization of a novel Micrococcus strain for bioremediation of strontium in radioactive residues. African Journal of Microbiology Research 6(4), pp. 851-858. 12. Bahig A. E., Aly E. A., Khaled A. A. and Amel K. A (2008). Isolation, Characterization and Application of Bacterial Population from Agricultural Soil at Sohag Province, Egypt. Malaysian Journal of Microbiology 4(2): 42- 50. 13. Perriello. (2005). Remediation of Metal Contaminants with Hydrocarbon Utilizing Bacteria. United States Patents: 1-19. 14. Wongsa, P., Tanaka, M., Ueno, A., Hasanuzzaman, M., Yumoto, I. and Okuyama, H. (2004). Isolation and Characterization of Novel Strains of Pseudomonas aeruginosa and Serratia marcescens Possessing High Efficiency to Degrade Gasoline, Kerosene, Diesel Oil, and Lubricating Oil. Journal of Current Microbiology 49: pp. 415–422 15. Ahemed, M. and Malik, A. (2011). Bioaccumulation of Heavy Metal by zinc Resistant Bacteria Isolated from Agricultural Soils Irrigated with Wastewater. Bacteriology Journal 2: 12-21. 16. Basha, S.A. and Rajaganesh, K. (2014). Microbial Bioremediation of Heavy Metals from Textile Industry Dye Effluents using Isolated Bacterial Strains. International Journal of Current Microbiology and Applied Science 3(5): 785-794. 17. Garbisu, C. and Alkorta, I. (2003). Basic concepts on heavy metal soil bioremediation, The European Journal of Mineral Processing and Environmental Protection 3 (1): pp. 58-66. 18. Dash, H.R., Mangwani, N., Chakraborty, J., Kumari, S. and Das, S. (2012). Marine bacteria: potential candidates for enhanced bioremediation. Applied Microbiology Biotechnology 97(2):561-71. 19. Mangum, S.J. (2009). Field Application Report: Optical Emission Spectrometry and ICP-Mass Spectrometry.1- 3. Available at:http://www.perkinelmer.com/content/applicationnotes/app_microwavedigestionmultiwave.pdf. Accessed March 2015. 20. Kamaruzzaman, B.Y., Eina, Z., John, B.A., and Jalal, K.C.A. (2011). Heavy Metal Accumulation Comercially Important Fishes of South West Malaysian Coast. Research Journal of Environment 5(6): 595-602. 21. Sarojam, P. (2010). Application Note: ICP-Optical Emission Spectroscopy.Available at: http://www.perkinelmer.com/cmsresources/images/4474318app_tracemetalsindrinkingwaterbyoptima7000.pdf. Accessed March, 2015. 22. Popovic, N.T., Rakovac, R.C. and Perovic, I.S.(2007). Commercial phenotypic tests (API 20E) in diagnosis.of fish bacteria: A review 52 (2): 49–53. 23. Benito, M. J. Aguez, M. M., Coardoba, M. G., Aranda, E., and Coardoba, J. J. (2000). Rapid differentiation of Staphylococcus aureus from staphylococcal species by arbitrarily primed-polymerase chain reaction. Letters in Applied Microbiology 31(5):368-373. 24. Benedetti, P., Rassu, M., Pavan, G., Sefton, A. and Pellizzer, G. (2011). Septic shock, pneumonia, and soft tissue infection due to Myroides odoratimimus: report of a case and review of Myroides infections 39: pp 161-165. 25. Xiao, Z., Zhu, X., Xi, L., Hou, X., Fang, L. and Lu, J.R. (2014). Biodegradation of C5-C 8 fatty acids and production of aroma volatiles by Myroides sp. ZB35 isolated from activated sludge. Journal of Microbiology 52(5):407-12. 26. Francis, A. J. (2005).Microbial Transformations of Radionuclides and Environmental Restoration through Bioremediation. Available at: http://www.bnl.gov/isd/documents/32628.pdf. Accessed April 2015. 27. Santhini, K., Myla, J., Sajani, S., and Usharani, G. (2009). Screening of Micrococcus Sp from Oil Contaminated Soil with Reference to Bioremediation. Botany Research International 2 (4): 248-252. 28. Ministry of Health. (2010). National Guidelines for Raw Drinking Water Quality. Available at: http://kmam.moh.gov.my/public-user/drinking-water-quality-standard.html. Accessed January 2015.
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norman
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12659 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12659 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal image/jpeg inches 96 96 norman 1420 762 34 34 2015-12-30 16:09:09 1420x762 6966-01-FH02-ESERI-15-04694.jpg UniSZA Private Access Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat] Malaysian Journal of Analytical Sciences The aim of this study was to identify and verify the potential bacteria as the bioremediation agent. It involved bacteria isolation, identification through Gram staining, analytical profile index (API) test and determine bioremediation activities by using inductively coupled plasma mass spectrometry (ICPMS). The soil and water sample were collected from downstream of Galing River, Kuantan Malaysia. Based on phenotypic identification and biochemical analysis, the bacteria present at the vicinity area are possibility of Myroides spp. and Micrococcus spp. These bacteria were proven as bioremediation agent based on the ICPMS result. The result 1 ppm of Zink (Zn), Lead (Pb), Arsenic (As), Selenium (Se), Cadmium (Cd), Manganese (Mn), and Indium (In) dwindled after the bacteria inoculated and incubated for seven days in mixture of base salt media (BSM) with the heavy metal elements. Therefore, this proves that the bacteria which are present at downstream of Galing River, Kuantan Malaysia are significant to help us in the bioremediation activity to decrease the heavy metal pollution in the environment. 19 6 Malaysian Society of Analytical Sciences Malaysian Society of Analytical Sciences 1405-1414 1. Hogan, M.C. (2014). Bacteria. Available at: http://www.eoearth.org/view/article/150368/. Accessed November 2014. 2. Ragini, G. and Pankaj, B. (2012). Cynobacteria: A comprehensive review. International Research Journal of Pharmacy 3(2): 1-5. 3. Mandal, A. K., Sarma, P. M., Singh, B., Jeyaseelan, C. P. Channashettar, V. A. Lal, B. and Datta, J. (2012) Bioremediation: An Environment Friendly Sustainable Biotechnological Solution for Remediation of Petroleum Hydrocarbon Contaminated Waste. ARPN Journal of Science and Technology 2: 1-12. 4. Alavijeh, P. K., Halimoon, N., Pauzi, Z., Johari, W. L. W., Karimi, B. (2014). Crude oil biodegradation using isolated bacteria from polluted soil: pp 127-129. 5. Naik, M. M., Pandey, A. and Dubey, S. K (2012). Bioremediation of Metals Mediated by Marine Bacteria. Microorganisms in Environmental Management Microbes and Environment: pp 665-682. 6. Sharma, S. (2012). Bioremediation: Features, Strategies and applications. Asian Journal of Pharmacy and Life Science 2 (2): 1-12. 7. Hamza, U. D., Mohammed, I. A. and Sale, A. (2012). Potentials of bacterial isolates in bioremediation of petroleum refinery wastewater. Journal of Applied Phytotechnology in Environmental Sanitation 1(3):131-138. 8. Poornima, K., Karthik, L., Swadhini, S. P., Mythili, S., and Sathiavelu, A. (2010). Degradation of Chromium by Using a Novel Strains of Pseudomonas Species. Journal of Microbial and Biochemical Technology, 2: 95- 99. 9. Igeno, I.M., Orovengua, E., Guijo, I.M., Merchán, F., Quesada and Blasco, R. (2007). Biodegradation of cyanide-containing wastes by Pseudomonas pseudoalcaligenes CECT5344. Available at: http://www.formatex.org/microbio/pdf/Pages100-107.pdf. Accessed March, 2015. 10. Vidali, M. (2001). Bioremediation. An overview. Available at: http://www.eolss.net/sample-chapters/c17/e6- 58-09-13.pdf. Accessed March 2015. 11. Salem, I. B., Sghaier, H., Trifi1, H., Héni, S., Khwaldia, K., Saidi, M. and Landoulsi, A. (2012). Isolation and characterization of a novel Micrococcus strain for bioremediation of strontium in radioactive residues. African Journal of Microbiology Research 6(4), pp. 851-858. 12. Bahig A. E., Aly E. A., Khaled A. A. and Amel K. A (2008). Isolation, Characterization and Application of Bacterial Population from Agricultural Soil at Sohag Province, Egypt. Malaysian Journal of Microbiology 4(2): 42- 50. 13. Perriello. (2005). Remediation of Metal Contaminants with Hydrocarbon Utilizing Bacteria. United States Patents: 1-19. 14. Wongsa, P., Tanaka, M., Ueno, A., Hasanuzzaman, M., Yumoto, I. and Okuyama, H. (2004). Isolation and Characterization of Novel Strains of Pseudomonas aeruginosa and Serratia marcescens Possessing High Efficiency to Degrade Gasoline, Kerosene, Diesel Oil, and Lubricating Oil. Journal of Current Microbiology 49: pp. 415–422 15. Ahemed, M. and Malik, A. (2011). Bioaccumulation of Heavy Metal by zinc Resistant Bacteria Isolated from Agricultural Soils Irrigated with Wastewater. Bacteriology Journal 2: 12-21. 16. Basha, S.A. and Rajaganesh, K. (2014). Microbial Bioremediation of Heavy Metals from Textile Industry Dye Effluents using Isolated Bacterial Strains. International Journal of Current Microbiology and Applied Science 3(5): 785-794. 17. Garbisu, C. and Alkorta, I. (2003). Basic concepts on heavy metal soil bioremediation, The European Journal of Mineral Processing and Environmental Protection 3 (1): pp. 58-66. 18. Dash, H.R., Mangwani, N., Chakraborty, J., Kumari, S. and Das, S. (2012). Marine bacteria: potential candidates for enhanced bioremediation. Applied Microbiology Biotechnology 97(2):561-71. 19. Mangum, S.J. (2009). Field Application Report: Optical Emission Spectrometry and ICP-Mass Spectrometry.1- 3. Available at:http://www.perkinelmer.com/content/applicationnotes/app_microwavedigestionmultiwave.pdf. Accessed March 2015. 20. Kamaruzzaman, B.Y., Eina, Z., John, B.A., and Jalal, K.C.A. (2011). Heavy Metal Accumulation Comercially Important Fishes of South West Malaysian Coast. Research Journal of Environment 5(6): 595-602. 21. Sarojam, P. (2010). Application Note: ICP-Optical Emission Spectroscopy.Available at: http://www.perkinelmer.com/cmsresources/images/4474318app_tracemetalsindrinkingwaterbyoptima7000.pdf. Accessed March, 2015. 22. Popovic, N.T., Rakovac, R.C. and Perovic, I.S.(2007). Commercial phenotypic tests (API 20E) in diagnosis.of fish bacteria: A review 52 (2): 49–53. 23. Benito, M. J. Aguez, M. M., Coardoba, M. G., Aranda, E., and Coardoba, J. J. (2000). Rapid differentiation of Staphylococcus aureus from staphylococcal species by arbitrarily primed-polymerase chain reaction. Letters in Applied Microbiology 31(5):368-373. 24. Benedetti, P., Rassu, M., Pavan, G., Sefton, A. and Pellizzer, G. (2011). Septic shock, pneumonia, and soft tissue infection due to Myroides odoratimimus: report of a case and review of Myroides infections 39: pp 161-165. 25. Xiao, Z., Zhu, X., Xi, L., Hou, X., Fang, L. and Lu, J.R. (2014). Biodegradation of C5-C 8 fatty acids and production of aroma volatiles by Myroides sp. ZB35 isolated from activated sludge. Journal of Microbiology 52(5):407-12. 26. Francis, A. J. (2005).Microbial Transformations of Radionuclides and Environmental Restoration through Bioremediation. Available at: http://www.bnl.gov/isd/documents/32628.pdf. Accessed April 2015. 27. Santhini, K., Myla, J., Sajani, S., and Usharani, G. (2009). Screening of Micrococcus Sp from Oil Contaminated Soil with Reference to Bioremediation. Botany Research International 2 (4): 248-252. 28. Ministry of Health. (2010). National Guidelines for Raw Drinking Water Quality. Available at: http://kmam.moh.gov.my/public-user/drinking-water-quality-standard.html. Accessed January 2015.
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| spellingShingle |
Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat]
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| summary |
The aim of this study was to identify and verify the potential bacteria as the bioremediation agent. It involved bacteria isolation, identification through Gram staining, analytical profile index (API) test and determine bioremediation activities by using inductively coupled plasma mass spectrometry (ICPMS). The soil and water sample were collected from downstream of Galing River, Kuantan Malaysia. Based on phenotypic identification and biochemical analysis, the bacteria present at the vicinity area are possibility of Myroides spp. and Micrococcus spp. These bacteria were proven as bioremediation agent based on the ICPMS result. The result 1 ppm of Zink (Zn), Lead (Pb), Arsenic (As), Selenium (Se), Cadmium (Cd), Manganese (Mn), and Indium (In) dwindled after the bacteria inoculated and incubated for seven days in mixture of base salt media (BSM) with the heavy metal elements. Therefore, this proves that the bacteria which are present at downstream of Galing River, Kuantan Malaysia are significant to help us in the bioremediation activity to decrease the heavy metal pollution in the environment.
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| title |
Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat]
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| title_full |
Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat]
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| title_fullStr |
Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat]
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| title_full_unstemmed |
Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat]
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| title_short |
Assessment on bacteria in the heavy metal bioremediation [Penilaian ke atas bakteria dalam bioremediasi logam berat]
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| title_sort |
assessment on bacteria in the heavy metal bioremediation [penilaian ke atas bakteria dalam bioremediasi logam berat]
|