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Effects of enzymatic hydrolysis on lipid extraction from Chlorella vulgaris

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  • Cho, Hyeon-Soo
  • Oh, You-Kwan
  • Park, Soon-Chul
  • Lee, Jae-Wook
  • Park, Ji-Yeon

Abstract

In this study, the effects of enzymatic hydrolysis on lipid extraction from microalga (Chlorella vulgaris) were investigated prior to biodiesel production. The initial fatty acids content of C. vulgaris was 87.6 mg/g cell. The microalgal cell walls were hydrolyzed by cellulases and then their lipid fractions were extracted using various organic solvents such as hexane, methanol, and chloroform. Optimal pH and temperature for the enzymatic hydrolysis were pH 4.8 and 50 °C, respectively, and the maximal hydrolysis yield was 85.3%, which was achieved after 72 h. After the enzymatic hydrolysis, the lipid extraction yield by the organic solvents was improved compared to when there was no enzymatic hydrolysis process, by 1.29–1.73-fold depending on the solvents used. The total fatty acid methyl ester (FAME) productivity through the enzymatic hydrolysis was higher than when there was no enzymatic hydrolysis, by 1.10–1.69-fold depending on the solvents used. When lipid was extracted from the C. vulgaris after the enzymatic hydrolysis in chloroform-methanol solution, FAME productivity was 59.4 mg FAME/g cell.

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  • Cho, Hyeon-Soo & Oh, You-Kwan & Park, Soon-Chul & Lee, Jae-Wook & Park, Ji-Yeon, 2013. "Effects of enzymatic hydrolysis on lipid extraction from Chlorella vulgaris," Renewable Energy, Elsevier, vol. 54(C), pages 156-160.
    • Handle: RePEc:eee:renene:v:54:y:2013:i:c:p:156-160
    DOI: 10.1016/j.renene.2012.08.031
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    References listed on IDEAS

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    1. Marchetti, J.M. & Miguel, V.U. & Errazu, A.F., 2007. "Possible methods for biodiesel production," Renewable and Sustainable Energy Reviews, Elsevier, vol. 11(6), pages 1300-1311, August.
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    1. Guo, Haipeng & Chen, Houming & Fan, Lu & Linklater, Andrew & Zheng, Bingsong & Jiang, Dean & Qin, Wensheng, 2017. "Enzymes produced by biomass-degrading bacteria can efficiently hydrolyze algal cell walls and facilitate lipid extraction," Renewable Energy, Elsevier, vol. 109(C), pages 195-201.
    2. Choi, Sun-A & Oh, You-Kwan & Jeong, Min-Ji & Kim, Seung Wook & Lee, Jin-Suk & Park, Ji-Yeon, 2014. "Effects of ionic liquid mixtures on lipid extraction from Chlorella vulgaris," Renewable Energy, Elsevier, vol. 65(C), pages 169-174.
    3. Park, Ji-Yeon & Kim, Min-Cheol & Cheng, Jun & Yang, Weijuan & Kim, Deog-Keun, 2020. "Extraction of microalgal oil from Nannochloropsis oceanica by potassium hydroxide-assisted solvent extraction for heterogeneous transesterification," Renewable Energy, Elsevier, vol. 162(C), pages 2056-2065.
    4. Zhang, Yi & Kong, Xiaoying & Wang, Zhongming & Sun, Yongming & Zhu, Shunni & Li, Lianhua & Lv, Pengmei, 2018. "Optimization of enzymatic hydrolysis for effective lipid extraction from microalgae Scenedesmus sp," Renewable Energy, Elsevier, vol. 125(C), pages 1049-1057.
    5. Dong, Tao & Knoshaug, Eric P. & Pienkos, Philip T. & Laurens, Lieve M.L., 2016. "Lipid recovery from wet oleaginous microbial biomass for biofuel production: A critical review," Applied Energy, Elsevier, vol. 177(C), pages 879-895.
    6. Singh, Bhaskar & Guldhe, Abhishek & Rawat, Ismail & Bux, Faizal, 2014. "Towards a sustainable approach for development of biodiesel from plant and microalgae," Renewable and Sustainable Energy Reviews, Elsevier, vol. 29(C), pages 216-245.
    7. Zhang, Yi & Kang, Xihui & Wang, Zhongming & Kong, Xiaoying & Li, Lianhua & Sun, Yongming & Zhu, Shunni & Feng, Siran & Luo, Xinjian & Lv, Pengmei, 2018. "Enhancement of the energy yield from microalgae via enzymatic pretreatment and anaerobic co-digestion," Energy, Elsevier, vol. 164(C), pages 400-407.
    8. Park, Ji-Yeon & Lee, Kyubock & Choi, Sun-A & Jeong, Min-Ji & Kim, Bohwa & Lee, Jin-Suk & Oh, You-Kwan, 2015. "Sonication-assisted homogenization system for improved lipid extraction from Chlorella vulgaris," Renewable Energy, Elsevier, vol. 79(C), pages 3-8.
    9. Bruno Rafael de Almeida Moreira & Ronaldo da Silva Viana & Victor Hugo Cruz & Paulo Renato Matos Lopes & Celso Tadao Miasaki & Anderson Chagas Magalhães & Paulo Alexandre Monteiro de Figueiredo & Luca, 2020. "Anti-Thermal Shock Binding of Liquid-State Food Waste to Non-Wood Pellets," Energies, MDPI, vol. 13(12), pages 1-26, June.

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