Biofuel co-products as livestock feed - Opportunities and challenges

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Micro-algae for fuel and use of spent biomass for feed and for other uses 445Studies, University of Malaya, Kuala Lumpur, Malaysia. FAO,Rome, Italy. Available at http://www.fao.org/docrep/004/ac155E/AC155E07.htm#ch6 Accessed 17 October 2011.Plaza, M., Herrero, M., Cifuentes, A. & Ibanez, E. 2009.Innovative natural functional ingredients from micro-algae.Journal of Agricultural and Food Chemistry, 57: 7159–7170.Posten, C. 2009. Design principles of photo-bioreactors forcultivation of micro-algae. Engineering in Life Sciences,9(3): 165–177.Prakash, J., Pushparaj, B., Carlozzi, P., Torzillo, G.,Montaini, E. & Materassi, R. 1997. Micro-algae dryingby a simple solar device. International Journal Solar Energy,18(4): 303–311.Pulz, O. 2001. Photobioreactors: production systems forphototrophic microorganisms. Applied Microbiology andBiotechnology, 57: 287–293.Pulz, O. & Gross, W. 2004. Valuable products frombiotechnology of micro-algae. Applied Microbiology andBiotechnology, 65(6): 635–648.Pyle, D.J., Garcia, R.A. & Wen, Z. 2008. Producingdocosahexanoic acid (DHA)-rich algae from biodiesel derivedcrude glycerol: Effects of impurities on DHA production andalgal biomass composition. Journal of Agricultural and FoodChemistry, 56(11): 3933–3939.Qasim, R. & Barkati, S. 1985. Ascorbic acid and dihydroascorbicacid contents of marine algal species from Karachi.Pakistan Journal of Scientific and Industrial Research,28(2): 129–133.Rajkumar, P.D.D., Bansal, D.D., Mishra, S., Mohammed, A.,Arora, R., Ashok, S., Rakesh, K.S. & Rajendra, P.T. 2010.Extremophiles: sustainable resource of natural compoundsextremolytes.pp. 279–294, in: O.V. Singh and S.P. Harvey(editors). Sustainable Biotechnology. Sources of RenewableEnergy. Springer Books.Ramachandra, T.V., Mahapatra, D.M. & Karthick, B.2009. Milking diatoms for sustainable energy: biochemicalengineering versus gasoline-secreting diatom solar panels.Industrial & Engineering Chemistry Research, 48: 8769–8788.Rao, A.R., Sarada, R., Baskaran, V. & Ravishankar, G.A.2006. Antioxidant activity of Botryococcus braunii extractelucidated in in vitro models. Journal of Agricultural andFood Chemistry, 54(13): 4593–4599.Ravishankar, G.A., Sarada, R., Kamath, B.S. & Namitha,K.K. 2008. Food applications of algae. pp. 491–524, in: K.Shetty, G. Paliyath, A. Pometto and R.E. Levin (editors). FoodBiotechnology. CRC press.Renaud, S.M., Thinh, L.V. & Parry, D.L. 1999. The grosschemical composition and fatty acid composition of 18species of tropical Australia micro-algae for possible use inmariculture. Aquaculture, 170: 147–159.Rodolfi, L., Zittelli, C.G., Bassi, N., Padovani, G., Biondi, N.,Bonini, G. & Tredici, M.R. 2009. Micro-algae for oil: strainselection, induction of lipid synthesis and outdoor masscultivation in a low cost photobioreactor. Biotechnology andBioengineering, 102(1): 100–112.Roman, B., Alvarez-Pez, J.M., Acien Fernandez, F.G. &Molina Grima, E. 2002. Recovery of pure B-phycoerythrinfrom the micro-alga Porphyridium cruentum. Journal ofBiotechnology, 93: 73–85.Salvo, R., Reich, A., Dykes Waite, H.H. & Teixera, R. 2011.Lipid extraction from micro-algae using a single ionic liquid.US patent Application number 20110130551.Samori, C., Samori, G. & Fabbri, D. 2010. Extraction ofhydrocarbons from micro-algae Botryococcus braunii withswitchable solvents. Bioresource Technology, 110(9): 3274–3279.Santos, M.C., Noyalo, P.T., Olvera, R.R., Lopez, J.O. &Villanueva, R.O.C. 2004. Extraction and purification ofphycocyanin from Calothrix spp. Process Biochemistry,39(2): 2047–2052.Sarada, R. 2007 [unpublished]. Production of bio-energymolecules (hydrocarbons) from cultured green alga -Botryococcus. Completion report. DBT Ref No: BT/PR 2978/AGR/16/220/2002.Sawayama, S., Minowa, T. & Yokayama, S.Y. 1999.Possibility of renewable energy production and carbondioxide mitigation by thermochemical liquefication of microalgae.Biomass and Bioenergy, 17(1): 33–39.Sheehan, J., Dunahay, T., Benemann, J. & Roessler, P.1998. A look back at the U.S. Department of Energy’sAquatic Species Program—Biodiesel from Algae. NationalRenewable Energy Laboratory. U.S. Department of Energy.Shi, X.M. & Chen, F. 2002. High-yield production of luteinby the green micro-alga Chlorella protothecoides inheterotrophic fed-batch culture. Biotechnology Progress,18(4): 723–727.Shi, X.M., Chen, F., Yuan, J.P. & Chen, H. 1997. Heterotrophicproduction of lutein by selected Chlorella strains. Journal ofApplied Phycology, 9(5): 445–450.Sialve, B., Bernet, N. & Bernard, O. 2009. Anaerobicdigestion of micro-algae as a necessary step to makemicro-algal biodiesel sustainable. Biotechnology Advances,29: 409–416.Sijtsma, L. & Swaaf, M.E. 2004. Biotechnological productionand applications of omega-3 poly unsaturated fatty acidDHA. Applied Microbiology and Biotechnology, 64: 146–153.Silva, G.P., Mack, M. & Contiero, J. 2009. Glycerol: Apromising and abundant carbon source for industrialmicrobiology. Biotechnology Advances, 27(1): 30–39.Singh, S., Bhushan, K.N. & Banerjee, U.C. 2005. Bioactivecompounds from cyanobacteria and micro-algae: Anoverview. Critical Reviews in Biotechnology, 25(3): 73–95.Skjanes, K., Lindblad, P. & Muller, J. 2007. Bio-CO 2 – amultidisciplinary, biological approach using solar energy tocapture CO 2 while producing H 2 and high value products.Biomolecular Engineering, 24: 405–413.
446Biofuel co-products as livestock feed – Opportunities and challengesSolibami, V.J. & Kamat, S.Y. 1985. Distribution of tocopherol(Vitamin E) in marine algae from Goa, west coast of India.Indian Journal of Marine Science, 14: 228–229.Spoehr, H.A. & Milner, H.W. 1949. The chemical compositionof Chlorella: effect of environment conditions. PlantPhysiology, 24: 120–149.Spolaore, P., Cassan, C.J., Duran, E. & Isambert, A.2006. Commercial applications of micro-algae. Journal ofBioscience and Bioengineering, 101(2): 87–96.Storebakken, T. 1988. Krill as a potential feed source forsalmonids. Aquaculture, 70: 193–205.Subramaniam, R., Dufreche, S., Zappi, M. & Bajpai, R.2010. Microbial lipids from renewable resources: productionand characterization. Journal of Industrial Microbiology andBiotechnology, 37(12): 1271–1287.Svensson, J. & Adlercreutz, P. 2008. Identification oftriacylglycerols in the enzymatic transesterification ofrapeseed and butter oil. European Journal of Lipid Scienceand Technology, 110(11): 1007–1013.Tan, C.K. & Johns, M.R. 1996. Screening of diatoms forheterotrophic eicosapentaenoic acid production. Journal ofApplied Phycology, 8: 59–64.Torrissen, O.J., Hardy, W.H. & Shearer, K.D. 1989.Pigmentation of salmonids – carotenoid deposition andmetabolism. Reviews in Aquatic Science, 1: 209–227.Tredici, M.R. & Materassi, R. 1992. From open pondsto vertical alveolar panels: the Italian experience in thedevelopment of reactors for the mass cultivation ofphototrophic microorganisms. Journal of Applied Phycology,4: 221–231.Tripathi, U., Sarada, R., Rao, R.S. & Ravishankar, G.A. 1999.Production of astaxanthin in Haematococcus pluvialis culturedin various media. Bioresource Technology, 68: 197–199.Uduman, N., Qi, Y., Danquah, M.K., Forde, G.M. &Hoadley, A. 2010. Dewatering of micro-algal cultures: amajor bottleneck to algae-based fuels. Journal of Renewableand Sustainable Energy, 2(1): Art. no. 012701 15 p.Urbani, R., Magaletti, E., Sist, P. & Cicero, A.M. 2005.Extracellular carbohydrates released by the marine diatomsCylindrotheca closterium, Thalassiosira pseudonana andSkeletonema costatum: Effect of P-depletion and growthstatus. Science of the Total Environment, 335(1-3): 300–306.Venkataraman, L.V., Becker, W.E., Rajasekaran, T. &Mathew, K.R. 1980. Investigations on the toxicology andsafety of algal diets in albino rats. Food and CosmeticToxicology, 18(3): 271–275.Vlad, M., Bordas, E., Caseanu, E., Uza, G., Creteanu, E. &Polinicenco, C. 1995. Effect of cuprofilin on experimentalatherosclerosis. Biological Trace Elements Research,48(1): 99–109.Voltolina, D., Gomez-Villa, H. & Correa, G. 2005.Nitrogen removal and recycling by Scenedesmus obliquusin semicontinuous cultures using artificial waste waterand a simulated light and temperature cycle. BioresourceTechnology, 96(3): 359–362.Wang, B., Li, Y., Wu, N. & Lan, C.Q. 2008. CO 2 bio-mitigationusing micro-algae. Applied Microbial Biotechnology,79: 707–718.Wen, Z.Y. & Chen, F. 2003. Heterotrophic production ofeicosapentaenoic acid by micro-algae. BiotechnologyAdvances, 21: 273–294.Wood, B.J.B. 1974. Fatty acids and saponifiable lipids. AlgalPhysiology and Biochemistry. Botanical Monographs. Vol 10.Edited by W.D.P. Stewart. University of California Press, USA,and Blackwell Science Publishers. UK.Yang, J., Xu, M., Zhang, X., Hu, Q., Sommerfeld, M. &Chen, Y. 2011. Life-cycle analysis on biodiesel productionfrom micro-algae: Water footprint and nutrients balance.Biotechnology, 102: 159–165.Yazdani, S.S. & Gonzalez, R. 2007. Anaerobic fermentationof glycerol: A path to economic viability for the biofuelsindustry. Current Opinion in Biotechnology, 18(3): 213–219.Yoon, R.H. & Luttrell, G.H. 1989. The effect of bubble sizeon fine particle flotation. Mineral Processing and ExtractiveMetallurgy, 5: 101–122.Yun, Y.S., Lee, S.B., Park, J.M., Lee, C.I. & Yang, J.W.1997. Carbon dioxide fixation by algal cultivation usingwaste water nutrients. Journal of Chemical Technology andBiotechnology, 69(4): 451–455.
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BIOFUEL CO-PRODUCTS AS LIVESTOCK FE
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Recommended citationFAO. 2012. Biof
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vco-products to swine - Feeding cru
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viiCHAPTER 22Use of Pongamia glabra
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ixPrefaceHumans are faced with majo
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xiiCBMCBSCCDSCCKCDOCDSCFCFBCFRCGECI
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xivHCHOHClHCNHisH-JPKMHMCHPDDGHPDDG
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xviPPbPCVPDPEMPFADPhePJPKCPKEPKMPKO
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xviiiWBPWCGFWDGWDGSWDGSHWPCWTWWWNSK
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10Biofuel co-products as livestock
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35Chapter 3Impact of United States
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Impact of United States biofuels co
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101Chapter 6Hydrogen sulphide: synt
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Hydrogen sulphide in cattle fed co-
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155Chapter 8Utilization of crude gl
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Utilization of crude glycerin in be
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209Chapter 11Co-products from biofu
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Co-products from biofuel production
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275Chapter 15Sustainable and compet
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Sustainable and competitive use of
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291Chapter 16Scope for utilizing su
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Scope for utilizing sugar cane baga
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303Chapter 17Camelina sativa in pou
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Camelina sativa in poultry diets: o
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311Chapter 18Utilization of lipid c
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Utilization of lipid co-products of
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351Chapter 21Use of detoxified jatr
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Use of detoxified jatropha kernel m
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379Chapter 22Use of Pongamia glabra
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Page 486 and 487: 467Chapter 26An assessment of the p
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Biofuels: their co-products and wat
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501Chapter 28Utilization of co-prod
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Utilization of co-products of the b
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523Contributing authorsSouheila Abb
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Contributing authors 525for the Fee
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Contributing authors 527Friederike
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Contributing authors 529Sustainable
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Contributing authors 531During the
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Contributing authors 533(Hons.) and
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