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Progress in Chemistry 2010, Vol. 22 Issue (06): 1221-1232 Previous Articles   

• Invited Article •

Advances on Technology of Microalgal High-lipid Production

Yao Ru1; Cheng Lihua2**; Xu Xinhua2; Zhang Lin1; Chen Huanlin1   

  1. (1.Department of Chemical and Biochemical Engineering, Zhejiang University, Hangzhou  310027, China;2.College of Environmental and Resource Sciences, Hangzhou 310027, China)
  • Received: Revised: Online: Published:
  • Contact: Cheng Lihua E-mail:chenglihua@zju.edu.cn
  • Supported by:

    National Natural Science Foundation of China

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Recently, bio-fuels receive extensive attention as a renewable and environmental friendly alternative energy source due to the global issues of both greenhouse effects and conventional fossil fuels shortage. Microalgae, with the merits of environmental adaptability, high photosynthetic efficiency, neutral net carbon value and high lipid content, has become one of the most important raw materials for bio-fuels production, especially for the biodiesel production. In this paper, the advances of technology in microalgal culture with high lipid content are reviewed worldwide. The selection of high-lipid microalgae species, high-density culture of high-lipid microalgae and approaches to increase both the microalgal lipid content and the lipid production rate are discussed. The feasibility of microalgal lipid metabolism regulated by genetic engineering technology is then elaborated. The intensified microalgal culture modes using the membrane bioreactor integrated with CO2 exhaust gas as the carbon source are finally introduced. The integrated technology will further reduce the cost for microalgal lipid production and whilst making this process to be economical for the production of biodiesel.

Contents
1 Screening and Culture of High-lipid Microalgae
1.1 Screening of High-lipid Microalgae Species
1.2 High-density Culture of High-lipid Microalgae
2 Mechanism of Carbon Sequestration and Lipid Production by Microalgae
2.1 Carbon Sequestration by Microalgae and Its Connection with Lipid Metabolism
2.2 Mechanism of Microalgal Lipid Biosynthesis
3 Transfromation of Microalgae by Genetic Engineering Methodsv
3.1 Acetyl-coenzyme A Carboxylase (ACCase)
3.2 Diacylglycerol Acyl-transferase (DGAT) 3.3 Phosphoenolpyruvate Carboxylase (PEPC)
3.4 Problems Remained in Microalgae Transfromation by Genetic Engineering Methods
4 Culture Technology for Microalgal Lipid Content and Productivity Enhancement
5 Intensified Microalgal Culture by Membrane Bioreactor
6 Outlook

Key words: high-lipid microalgae, triacylglycerols, biodiesel, CO2 removal, membrane bioreactor

CLC Number: 

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[2] Zhang Fang, Cheng Lihua, Xu Xinhua, Zhang Lin, Chen Huanlin. Technologies of Microalgal Harvesting and Lipid Extraction [J]. Progress in Chemistry, 2012, (10): 2062-2072.
[3] Feng Guodong, Cheng Lihua, Xu Xinhua, Zhang Lin, Chen Huanlin. Strategies in Genetic Engineering of Microalgae for High-Lipid Production [J]. Progress in Chemistry, 2012, 24(07): 1413-1426.
[4] . Applications of Supercritical Methanol in Chemical Reactions [J]. Progress in Chemistry, 2010, 22(05): 796-802.
[5] Du Zexue Yang Guojun. Biodiesel from Woody Oil-bearing Plants——Development of Biodiesel Industry from Jatropha Curcas L. [J]. Progress in Chemistry, 2009, 21(11): 2341-2348.
[6] Liu Hongjuan1,Du Wei2,Liu Dehua2*. Progress of the biodiesel and 1,3-Propanediol Integrated Production [J]. Progress in Chemistry, 2007, 19(0708): 1185-1189.
[7] Min Enze*|Yao Zhilong. The Development of Biodiesel Industry in Recent Years--Peculiarity, Predicament and Countermeasures [J]. Progress in Chemistry, 2007, 19(0708): 1050-1059.
[8] Chen, xi1**,Han Zhiqun2,Kong Fanhua1,Hu Xuteng1 . Exploitation and Utilization of Bio-Energy [J]. Progress in Chemistry, 2007, 19(0708): 1091-1097.
[9] Enze Min*. Developing Biorefinery by Utilizing Agriculture and Forestry Biomass Resources:Striding Forward [J]. Progress in Chemistry, 2006, 18(0203): 131-141.