影响微藻规模化培养的因素

doi:10.1016/S1872-2067(11)60497-X

摘要/Abstract

摘要： 概述了微藻生物能源技术中的微藻规模化培养的研究现状, 从藻种筛选、代谢机理、培养条件和光生物反应器几个不同的角度阐述了影响微藻规模化培养的因素, 为微藻生物能源的发展及光生物反应器的研发提供建议与思路.

Abstract: Biofuel from microalgae is a long term strategy to solve the energy crisis. It is a new area of biological engineering and process engineering that consists of the isolation and characterization of microalgae species, mass cultivation of microalgae, harvesting and post-processing. The successful mass cultivation of microalgae is one of its main challenges. Several factors influencing the mass cultivation of microalgae are discussed, such as microalgae species, metabolic mechanism, culture conditions and the photobioreactor. This paper will help the development of biofuels from microalgae and its photobioreactor.

Key words: Microalgae, Biofuel, Photobioreactor, Lipid content, Mass cultivation

朱俊英, 荣峻峰, 宗保宁. 影响微藻规模化培养的因素[J]. 催化学报, 2013, 34(1): 80-100.

ZHU Jun-Ying, RONG Jun-Feng, ZONG Bao-Ning. Factors in mass cultivation of microalgae for biodiesel[J]. Chinese Journal of Catalysis, 2013, 34(1): 80-100.

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参考文献

[1] Amaro H M, Guedes A C, Malcata F X. Appl Energ, 2011, 88: 3402
[2] Min E Z, Yao Zh L. Progr Chem (闵恩泽, 姚志龙. 化学进展), 2007, 19: 1050
[3] Apt K E, Behrens P W. J Phycol, 1999, 35: 215
[4] Rodolfi L, Zittelli G C, Bassi N, Padovani G, Biondi N, Bonini G, Tredici M R. Biotechnol Bioeng, 2008, 102: 100
[5] Brennan L, Owende P. Renew Sust Energ Rev, 2010, 14: 557
[6] Yang S, Chen Ch Y, Zhao Sh L, Niu Y H, Li L. Yunnan Chem Technol (杨苏, 陈朝银, 赵声兰, 牛耀辉, 李立. 云南化工), 2006, 33(3): 49
[7] Wang J, Yang S L, Cong W, Cai Zh L. Chin J Proc Eng (王军, 杨素玲, 从威, 蔡昭玲. 过程工程学报), 2003, 3: 141
[8] de-Bashan L E, Antoun H, Bashan Y. FEMS Microbiol Ecol, 2005, 54: 197
[9] Wen J, Sun Y, Li B Sh, Zhu R X, Jiang Y J, Wen H Ch, Zhang Y K. Mi-crobiol China (文锦, 孙远, 李宝硕, 朱瑞雪, 蒋云江, 温皓程, 张永奎. 微生物通报), 2010, 37: 1721
[10] Perez-Garcia O, Escalante F M E, de-Bashan L E, Bashan Y. Water Res, 2011, 45: 11
[11] Chen G Q, Jiang Y, Chen F. Food Chem, 2007, 104: 1580
[12] Song D H, Hou L J, Shi D J. Chin J Biotechnol (宋东辉, 侯李君, 施定基. 生物工程学报), 2008, 24: 341
[13] Andersen R A, Kawachi M. Traditional Microalgae Isolation Techniques, In: Algal Culturing Techniques. Burlington: Elsevier Academic Press, 2005. Chapter 6, 83
[14] Li Y Q, Horsman M, Wang B, Wu N, Lan C Q. Appl Microbiol Bio-technol, 2008, 81: 629
[15] Khozin-Goldberg I, Cohen Z. Phytochemistry, 2006, 67: 696
[16] Lynn S G, Kilham S S, Kreeger D A, Interlandi S J. J Phycol, 2000, 36: 510
[17] Rao A R, Dayananda C, Sarada R, Shamala T R, Ravishankar G A. Biorescource Technol, 2007, 98: 560
[18] Yao R, Cheng L H, Xu X H, Zhang L, Chen H L. Progr Chem (姚茹, 程丽华, 徐新华, 张林, 陈欢林. 化学进展), 2010, 22: 1221
[19] Zhu Sh N, Wang Zh M, Shang Ch H, Zhou W Zh, Yang K, Yuan Zh H. Progr Chem (朱顺妮, 王忠铭, 尚常花, 周卫征, 杨康, 袁振宏. 化学进展), 2011, 23: 2169
[20] Arabolaza A, Rodriguez E, Altabe S, Alvarez H, Gramajo H. Appl Environ Microbiol, 2008, 74: 2573
[21] Dahlqvist A, Stahl U, Lenman M, Banas A, Lee M, Sandager L, Ronne H, Stymne S. Proc Natl Acad Sci, 2000, 97: 6487
[22] Riekhof W R, Sears B B, Benning C. Eukaryot Cell, 2005, 4: 242
[23] National Algal Biofuels Technology Roadmap. U.S. Department of Energy, Energy Efficiency and Renewable Energy, 2010
[24] Rabbani S, Beyer P, Von Lintig J, Hugueney P, Kleinig H. Plant Physiol, 1998, 116: 1239
[25] Zhekisheva M, Boussiba S, Khozin-Goldberg I, Zarka A, Cohen Z. J Phycol, 2002, 38: 325
[26] Chen M, Tang H Y, Ma H Z, Holland T C, Ng K Y S, Salley S O. Biore-source Technol, 2011, 102: 1649
[27] Feng G D, Cheng L H, Xu X H, Zhang L, Chen H L. Progr Chem (冯国栋, 程丽华, 徐新华, 张林, 陈欢林. 化学进展), 2012, 24: 1413
[28] Eriksen N T, Geest T, Iversen J J L. J Appl Phycol, 1996, 8: 345
[29] Cheng L H, Zhang L, Chen H L, Gao C. Sep Purif Technol, 2006, 50: 324
[30] Chen G Q, Chen F. Biotechnol Lett, 2006, 28: 607
[31] Oyang Zh R, Wen X B, Geng Y H, Mei H, Hu H J, Zhang G Y, Li Y G. J Wuhan Bot Res (欧阳峥嵘, 温小斌, 耿亚红, 梅洪, 胡鸿钧, 张捷艳, 李夜光. 武汉植物研究), 2010, 28: 49
[32] Liang Y, Mai K S, Sun Sh Ch, Yu D D. Mari Sci (梁英, 麦康森, 孙世春, 于道德. 海洋科学), 2002, 26: 48
[33] Solovchenko A E, Khozin-Goldberg I, Didi-Cohen S, Cohen Z, Merzlyak M N. J Appl Phycol, 2008, 20: 245
[34] Rohá?ek K, Barták M. Photosynthetica, 1999, 37: 339
[35] Hua R Ch (华汝成. 单细胞藻类的培养与利用. 北京: 中国农业出版社). Beijing: China Agriculture Press, 1986
[36] Janssen M, Slenders P, Tramper J, Mur L R, Wijffels R. Enzyme Microb Tech, 2001, 29: 298
[37] Cong W, Su Zh F, Xue Sh Ch, Yang Ch Y (从威, 苏贞峰, 薛升长, 杨成砚). CN Patent 101 899 385 A. 2010
[38] Cong W, Zhang Q H, Xue Sh Ch (从威, 张庆华, 薛升长). CN Patent 102 260 629 A. 2011
[39] Yin Z Q. Beijing: China Electric Power Press (殷志强. 中国可再生能源发展战略研究丛书-太阳能卷. 北京: 中国电力出版社), 2008
[40] Zhang Ch, Zou J Zh. Oceanol et Limnol Sin, 1997, 28: 599
[41] Li B, Ou L J, Lü S H. Mar Environ Sci, 2009, 28: 264
[42] Ding Y C, Gao Q, Liu J Y, Yi Y J, Liu J G, Lin W. Acta Ecol Sin (丁彦聪, 高群, 刘家尧, 衣艳君, 刘建国, 林伟. 生态学报), 2011, 31: 5307
[43] Wang L Zh, Wen H Ch, Zou Y, Zhou W W, Xie T H, Zhang Y K. Microbiology, 2010, 37: 336
[44] Yin C L, Liang Y, Zhang Q F. Fisheries Sci (尹翠玲, 梁英, 张秋丰. 水产科学), 2008, 27: 27
[45] Kolber Z, Zehr J, Falkowski P. Plant Physiol, 1988, 88: 923
[46] Evans C T, Scragg A H, Ratledge C. Eur J Biochem, 1983, 132: 609
[47] Li Ying, Lü S H, Xu N, Xie L Ch. J Ecol Sci (李英, 吕颂辉, 徐宁, 谢隆初. 生态科学), 2005, 24: 314
[48] Wen Sh Y, Zhao D Zh, Zhao L, Yang J H, Zhang F Sh, Wang L, Gao Sh G, Sun D. J Dalian Marit Univ (文世勇, 赵冬至, 赵玲, 杨建洪, 张丰收, 王林, 高树刚, 孙东. 大连海事大学学报), 2009, 35: 118
[49] Wu Y, Sun J M, Sun P H, Zhang D M. J Fisheries Chin (吴垠, 孙建明, 孙培海, 张德明. 水产学报), 2004, 28: 742
[50] Wang G D, Zhang L L, Wu Y, Sun J M. J Hydroecol (王国栋, 张丽莉, 吴垠, 孙建明. 水生态学杂志), 2008, 1(2): 35
[51] Zhang Q D, Lu C M, Feng L J, Lin Sh Q, Kuang T Y, Bai K Zh. Chin Bull Bot (张其德, 卢从明, 冯丽洁, 林世青, 匡廷云, 白克智. 植物学报), 1996, 38: 77
[52] Chiu S Y, Kao C Y, Huang T T, Lin C J, Ong S C, Chen C D, Chang J S, Lin C S. Bioresource Technol, 2011, 102: 9135
[53] Yang B, Chu Zh Sh, Jin X C, Yan F, Zeng Q R. Chin Environ Sci (杨波, 储昭升, 金相灿, 阎峰, 曾清如. 中国环境科学), 2007, 27: 54
[54] Zhu M, Zhang X Ch, Mao Y X. Period Ocean Univ Chin (朱明, 张学成, 茅云翔. 中国海洋大学学报), 2005, 35: 499
[55] Liu J L, Zhang S L. Chin J Biotechnol (刘晶张嗣良. 生物工程学报), 2000, 16(2): 119
[56] Wang Q, Qu Z M, Liu J L. Guangdong Agric Sci (王琴, 区子弁, 柳建良. 广东农业科学), 2011: 180
[57] Sheehan J, Dunahay T, Benemann J, Roessler P, National Renewa-ble Energy Lab., Golden, CO.: United States, 1998
[58] Ugwu C U, Ogbonna J C, Tanaka H. Process Biochem, 2005, 40: 3406
[59] Hsieh C H, Wu W T. Biochem Eng J, 2009, 46: 300
[60] Li X W, Li Y G, Shen G M, Yang D. Chin J Proc Eng (李兴武, 李元广, 沈国敏, 杨东. 过程工程学报), 2006, 6: 277
[61] Cong W, Liu M, Bao Y L (丛威, 刘明, 鲍亦璐). CN Patent 101948740A. 2011
[62] Chisti Y. Biotechnol Adv, 2007, 25: 294
[63] Scragg A H, Illman A M, Carden A, Shales S W. Biomass Bioenerg, 2002, 23: 67
[64] Travieso L, Hall D O, Rao K K, Benítez F, Sánchez E, Borja R. Int Biodeter Biodegr, 2001, 47: 151
[65] Hulatt C J, Thomas D N. Bioresource Technol, 2011, 102: 6687
[66] Hulatt C J, Thomas D N. Bioresource Technol, 2011, 102: 5775
[67] Yoon J H, Choi S S, Park T H. Bioresource Technol, 2012, 110: 430
[68] Jacob-Lopes E, Scoparo C H G, Lacerda L M C F, Franco T T. Chem Eng Process, 2009, 48: 306
[69] Rasoul-Amini S, Montazeri-Najafabady N, Mobasher M A, Ho-seini-Alhashemi S, Ghasemi Y. Appl Energ, 2011, 88: 3354
[70] Feng P, Deng Z, Hu Z, Fan L. Bioresource Technol, 2011, 102: 10577
[71] Richmond A, Zhang C W. J Biotechnol, 2001, 85: 259
[72] Doucha J, Lívanský K. J Appl Phycol, 2009, 21: 111
[73] Zhan W, Sang M, Li A F, Zhang Ch W. Renew Energ Resour (展望, 桑敏, 李爱芬, 张成武. 可再生能源), 2010, 28(3): 67
[74] Miu J L, Wang B, Kan G F, Ding Y, Jiang Y H, Hou X G, Li G Y. Mari Sci (缪锦来, 王波, 阚光锋, 丁燏, 姜英辉, 侯旭光, 李光友. 海洋科学), 2005, 29: 2
[75] Borowitzka M A. J Biotechnol, 1999, 70: 313
[76] Alías C B, López M C G M, Fernández F G A, Sevilla J M F, Sánchez J L G, Grima E M. Biotechnol Bioeng, 2004, 87: 723
[77] Chae S R, Hwang E J, Shin H S. Biores Technol, 2006, 97: 322
[78] Hu Q, Guterman H, Richmond A. Biotechnol Bioeng, 1996, 51: 51
[79] Hu Q, Faiman D, Richmond A. J Ferment Bioeng, 1998, 85: 230
[80] Sierra E, Acién F G, Fernández J M, García J L, González C, Molina E. Chem Eng J, 2008, 138: 136
[81] Doucha J, Lívanský K. US Patent 5 981 271. 1999
[82] Doucha J, Lívanský K. J Appl Phycol, 2006, 18: 811
[83] Rong J F, Huang X G, Zhou X H (荣峻峰, 黄绪耕, 周旭华). CN Patent 101 870 950 A. 2010
[84] Gorny R, Mason J P, Hilton G, Schwarz P. WO Patent 2011/034 567 A2. 2011
[85] Han Ch M, Yang J Q, Chen H T, Zhang H, Liu M Sh (韩春梅, 杨建强, 陈红涛, 张涵, 刘敏胜). CN Patent 101 735 948 A. 2010
[86] Liu T Zh, Zhang W, Chen Y, Peng X W, Chen X L, Chen L (刘天中, 张维, 陈昱, 彭小伟, 陈晓琳). CN Patent 102 206 570 A. 2010
[87] Sato T, Yamada D, Hirabayashi S. Energ Convers Manage, 2010, 51: 1196
[88] Slegers P M, Wijffels R H, van Straten G, van Boxtel A J B. Appl Energ, 2011, 88: 3342
[89] Qiu Ch T, Lin T, Zhang Q L, Xu H D, Chen Y Q, Gong M Ch. Chin J Catal (邱春天, 林涛, 张秋林, 徐海迪, 陈耀强, 龚茂初. 催化学报 ), 2011, 32: 1227