Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting

Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting

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internalnotes 1. Brennan, L. and P. Owende. (2010). Biofuels from microalgae - A review of technologies for production, processing, and extractions of biofuels and co-products. Renewable and Sustainable Energy Reviews, 14(2). 557 – 577. 2. Ahmad, A. L., Yasin, N. M., Derek, C. J. C. and Lim, J. K. (2011). Optimization of Microalgae Coagulation Process using Chitosan. Chemical Engineering Journal, 173(3): 879 – 882. 3. Zheng, H. Gao, Z. Yin, J. Tang, X. Ji, X. and Huang, H. (2012). Harvesting of Microalgae by Flocculation with Poly (γ-glutamic acid). Bioresource Technology. 112. 212 – 220. 4. Teixeira, C. M. L. L., Kirsten, F. V. and Teixeira, P. C. N. (2012). Evaluation of Moringa oleifera seed flour as a flocculating agent for potential biodiesel producer microalgae. Journal of Applied Phycology. 24(3). 557 – 563. 5. Muyibi, S. A. and Evison, L. M. (1995). Moringa Oleifera Seeds for Softening Hardwater. Water Research. 29(4): 1099 – 1104. 6. Ndabigengesere, A. and Narasiah, K. S. (1998). Quality of Water Treated by Coagulation using Moringa Oleifera Seeds. Water Research. 32(3). 781 – 791. 7. Bilanovic, D., Andargatchew, A., Kroeger, T. and Shelef, G. (2009). Freshwater and Marine Microalgae Sequestering Of CO2 At Different C And N Concentrations – Response Surface Methodology Analysis. Energy Conversion and Management. 50(2). 262 – 267. 8. De Godos, I., Mendoza, J. L., Acién, F. G., Molina, E., Banks, C. J., Heaven, S. and Rogalla, F. (2014). Evaluation of Carbon Dioxide Mass Transfer in Raceway Reactors for Microalgae Culture using Flue Gases. Bioresource Technology, 153: 307 – 314. 9. Chen, L., Zhang, G., Wang, L., Wu, W. and Ge, J. (2014). Zeta Potential of Limestone in A Large Range of Salinity. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 450: 1 – 8. 10. Moncho, A., F. Martı́nez-López and Hidalgo-Álvarez, R. (2001). Comparative Study of Theories of Conversion of Electrophoretic Mobility into ζ-potential. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 192(1–3). 215 – 226. 11. Ofir, E., Oren, Y. and Adin, A. (2001). Electroflocculation: The Effect of Zeta-potential on Particle Size. Desalination, 204(1–3): 33 – 38. 12. Kwaambwa, H. and Maikokera, R. (2007). A Fluorescence Spectroscopic Study of A Coagulating Protein Extracted from Moringa Oleifera Seeds. Colloids and surfaces B: Biointerfaces. 60(2): 213 – 220. 13. Hunter, R. J. (2001). Measuring Zeta Potential In Concentrated Industrial Slurries. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 195(1–3): 205 – 214. 14. Smoluchowski, M. (1967). Investigation into A Mathematical Theory of the Kinetics of Coagulation of Colloidal Solutions. Physical Chemistry 92:129 – 168. 15. Muyibi, S. A., Abas, S. A. A., Megat Johari, M. M., and Ahmadun, N. F. R. (2003). Enhanced Coagulation Efficiency of Moringa Oleifera Seeds through Selective Oil Extraction. IIUM Engineering Journal, 4(1): 1 – 11. 16. Beuckels, A., Depraetere, O., Vandamme, D., Foubert, I., Smolders, E. and Muylaert, K. (2013). Influence of organic matter on flocculation of Chlorella vulgaris by calcium phosphate precipitation. Biomass and Bioenergy, 54: 107 – 114. 17. Harith, Z. T., Yusoff, F. M., Mohamed, M. S., Shariff, M., Din, M. and Ariff, A. B. (2009). Effect of different flocculants on the flocculation performance of flocculation performance of microalgae, Chaetoceros calcitrans, cells. African Journal of Biotechnology, 8(21): 5971 – 5978. 18. Oh, H. M., Lee, S. J., Park, M. H., Kim, H. S., Kim, H. C., Yoon, J. H., Kwon, G. S and Yoon, B. D. (2001). Harvesting of Chlorella vulgaris using a bioflocculant from Paenibacillus sp. AM49. Biotechnology Letters, 23(15): 1229 – 1234. 19. Vandamme, D., Foubert, I., Meesschaert, B. and Muylaert, K. (2010). Flocculation of microalgae using cationic starch. Journal of Applied Phycology, 22(4): 525 – 530.
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resourceurl https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12954
spelling 12954 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12954 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal image/jpeg inches 729 96 96 norman 86 86 1415 2016-05-11 15:08:09 1415x729 7261-01-FH02-ESERI-16-05804.jpg UniSZA Private Access Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting Malaysian Journal of Analytical Sciences Microalgae is an economical and potential raw material of biomass energy, which offer a wide range of commercial potential to produce valuable substances for applications in aquaculture feed, pharmaceutical purposes and biofuels production. However, lack of an economical, efficient and convenient method to harvest microalgae is a bottleneck to boost their full-scale application. Hence, this study was performed to investigate the potentialities of Moringa oleifera seed derivatives as an environmentally biocoagulant to harvest microalgae Chlorella sp. biomass from the water column, which acts as a binder to coagulate particulate impurities to form larger aggregates. Results shown M. oleifera to have better biomass recovery of 122.51% as compared to 37.08% of alum at similar dosages of 10 mg·L-1 . In addition, it was found that the zeta potential values of mixed microalgaecoagulant suspension shows positive correlation on the flocculation parameters. For biomass recovery, the correlation for M. oleifera protein powder showed the R2 -value of 0.9565 whereas the control chemical flocculant, alum with the R2 -value of 0.7920. It was evidence that M. oleifera has a great potential in efficient and economical for environmentally microalgae harvesting and the adaptation of biological harvesting technology especially for the purpose of aquaculture feed in Malaysia. 20 2 Malaysian Society of Analytical Sciences Malaysian Society of Analytical Sciences 401-412 1. Brennan, L. and P. Owende. (2010). Biofuels from microalgae - A review of technologies for production, processing, and extractions of biofuels and co-products. Renewable and Sustainable Energy Reviews, 14(2). 557 – 577. 2. Ahmad, A. L., Yasin, N. M., Derek, C. J. C. and Lim, J. K. (2011). Optimization of Microalgae Coagulation Process using Chitosan. Chemical Engineering Journal, 173(3): 879 – 882. 3. Zheng, H. Gao, Z. Yin, J. Tang, X. Ji, X. and Huang, H. (2012). Harvesting of Microalgae by Flocculation with Poly (γ-glutamic acid). Bioresource Technology. 112. 212 – 220. 4. Teixeira, C. M. L. L., Kirsten, F. V. and Teixeira, P. C. N. (2012). Evaluation of Moringa oleifera seed flour as a flocculating agent for potential biodiesel producer microalgae. Journal of Applied Phycology. 24(3). 557 – 563. 5. Muyibi, S. A. and Evison, L. M. (1995). Moringa Oleifera Seeds for Softening Hardwater. Water Research. 29(4): 1099 – 1104. 6. Ndabigengesere, A. and Narasiah, K. S. (1998). Quality of Water Treated by Coagulation using Moringa Oleifera Seeds. Water Research. 32(3). 781 – 791. 7. Bilanovic, D., Andargatchew, A., Kroeger, T. and Shelef, G. (2009). Freshwater and Marine Microalgae Sequestering Of CO2 At Different C And N Concentrations – Response Surface Methodology Analysis. Energy Conversion and Management. 50(2). 262 – 267. 8. De Godos, I., Mendoza, J. L., Acién, F. G., Molina, E., Banks, C. J., Heaven, S. and Rogalla, F. (2014). Evaluation of Carbon Dioxide Mass Transfer in Raceway Reactors for Microalgae Culture using Flue Gases. Bioresource Technology, 153: 307 – 314. 9. Chen, L., Zhang, G., Wang, L., Wu, W. and Ge, J. (2014). Zeta Potential of Limestone in A Large Range of Salinity. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 450: 1 – 8. 10. Moncho, A., F. Martı́nez-López and Hidalgo-Álvarez, R. (2001). Comparative Study of Theories of Conversion of Electrophoretic Mobility into ζ-potential. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 192(1–3). 215 – 226. 11. Ofir, E., Oren, Y. and Adin, A. (2001). Electroflocculation: The Effect of Zeta-potential on Particle Size. Desalination, 204(1–3): 33 – 38. 12. Kwaambwa, H. and Maikokera, R. (2007). A Fluorescence Spectroscopic Study of A Coagulating Protein Extracted from Moringa Oleifera Seeds. Colloids and surfaces B: Biointerfaces. 60(2): 213 – 220. 13. Hunter, R. J. (2001). Measuring Zeta Potential In Concentrated Industrial Slurries. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 195(1–3): 205 – 214. 14. Smoluchowski, M. (1967). Investigation into A Mathematical Theory of the Kinetics of Coagulation of Colloidal Solutions. Physical Chemistry 92:129 – 168. 15. Muyibi, S. A., Abas, S. A. A., Megat Johari, M. M., and Ahmadun, N. F. R. (2003). Enhanced Coagulation Efficiency of Moringa Oleifera Seeds through Selective Oil Extraction. IIUM Engineering Journal, 4(1): 1 – 11. 16. Beuckels, A., Depraetere, O., Vandamme, D., Foubert, I., Smolders, E. and Muylaert, K. (2013). Influence of organic matter on flocculation of Chlorella vulgaris by calcium phosphate precipitation. Biomass and Bioenergy, 54: 107 – 114. 17. Harith, Z. T., Yusoff, F. M., Mohamed, M. S., Shariff, M., Din, M. and Ariff, A. B. (2009). Effect of different flocculants on the flocculation performance of flocculation performance of microalgae, Chaetoceros calcitrans, cells. African Journal of Biotechnology, 8(21): 5971 – 5978. 18. Oh, H. M., Lee, S. J., Park, M. H., Kim, H. S., Kim, H. C., Yoon, J. H., Kwon, G. S and Yoon, B. D. (2001). Harvesting of Chlorella vulgaris using a bioflocculant from Paenibacillus sp. AM49. Biotechnology Letters, 23(15): 1229 – 1234. 19. Vandamme, D., Foubert, I., Meesschaert, B. and Muylaert, K. (2010). Flocculation of microalgae using cationic starch. Journal of Applied Phycology, 22(4): 525 – 530.
spellingShingle Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting
summary Microalgae is an economical and potential raw material of biomass energy, which offer a wide range of commercial potential to produce valuable substances for applications in aquaculture feed, pharmaceutical purposes and biofuels production. However, lack of an economical, efficient and convenient method to harvest microalgae is a bottleneck to boost their full-scale application. Hence, this study was performed to investigate the potentialities of Moringa oleifera seed derivatives as an environmentally biocoagulant to harvest microalgae Chlorella sp. biomass from the water column, which acts as a binder to coagulate particulate impurities to form larger aggregates. Results shown M. oleifera to have better biomass recovery of 122.51% as compared to 37.08% of alum at similar dosages of 10 mg·L-1 . In addition, it was found that the zeta potential values of mixed microalgaecoagulant suspension shows positive correlation on the flocculation parameters. For biomass recovery, the correlation for M. oleifera protein powder showed the R2 -value of 0.9565 whereas the control chemical flocculant, alum with the R2 -value of 0.7920. It was evidence that M. oleifera has a great potential in efficient and economical for environmentally microalgae harvesting and the adaptation of biological harvesting technology especially for the purpose of aquaculture feed in Malaysia.
title Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting
title_full Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting
title_fullStr Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting
title_full_unstemmed Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting
title_short Moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. Harvesting
title_sort moringa oleifera seed derivatives as potential bio-coagulant for microalgae chlorella sp. harvesting

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