Abstract
The biochemical contents and biodiesel production ability of three microalgal strains grown under different sodium nitrate, sodium carbonate, and ferric ammonium citrate (iron) levels were investigated. The highest biomass and lipid contents were found in Scenedesmus sp., Chlorella sp., and Chlamydomonas sp. when grown in normal BG-11 containing sodium carbonate concentration at 0.03 g · L(-1) , and in normal BG-11 containing iron concentration (IC) at 0.009 or 0.012 g · L(-1) . Increasing the sodium nitrate level increased the biomass content, but decreased the lipid content in all three microalgae. Among the three microalgae, Scenedesmus sp. showed the highest total lipid yield of 0.69 g · L(-1) under the IC of 0.012 g · L(-1) . Palmitic and oleic acids were the major fatty acids of Scenedesmus sp. and Chlamydomonas sp. lipids. On the other hand, Chlorella sp. lipids were rich in palmitic, oleic, and linolenic acids, and henceforth contributing to poor biodiesel properties below the standard limits. The three isolated strains had a potential for biodiesel production. Nevertheless, Scenedesmus sp. from stone quarry pond water was the most suitable source for biodiesel production with tolerance toward the high concentration of ...Continue Reading
References
May 7, 1976·Analytical Biochemistry·M M Bradford
Jun 7, 2005·Bioresource Technology·Xiaoling Miao, Qingyu Wu
Nov 25, 2005·Plant Physiology·Christian Bölling, Oliver Fiehn
Sep 1, 2006·Nature·Michael J BehrenfeldDonald M Shea
Mar 14, 2007·Biotechnology Advances·Yusuf Chisti
Apr 10, 2007·Bioresource Technology·Ji-Yeon ParkJin-Suk Lee
Nov 13, 2007·Bioresource Technology·Zhi-Yuan LiuBai-Cheng Zhou
Aug 12, 2008·Bioresource Technology·María Jesús RamosAngel Pérez
May 12, 2009·Journal of Biotechnology·Noémie Manuelle Dorval CourchesneChristopher Q Lan
Jul 14, 2009·Applied and Environmental Microbiology·Claire Valiente MoroJacques Bohatier
Feb 16, 2010·Bioresource Technology·Andrew P DeanJon K Pittman
Jan 25, 2011·BMC Biotechnology·Magali SiautGilles Peltier
Jan 24, 2013·Bioresource Technology·Yu-Ting TsaiMing-Jer Lee
Jul 31, 2013·Journal of Bioscience and Bioengineering·Ramachandran Sivaramakrishnan, Karuppan Muthukumar
Feb 6, 2014·Bioresource Technology·Imran PanchaSandhya Mishra
Mar 29, 2014·AMB Express·Joseph K EiblGregory M Ross
May 16, 2014·Physiologia Plantarum·Omar El-Ansari, Brian Colman
Aug 29, 2014·Bioresource Technology·Hongqin Wu, Xiaoling Miao
Jul 6, 2015·Bioresource Technology·Imran PanchaSandhya Mishra
Oct 17, 2015·International Journal of Molecular Sciences·Krystian MiazekDorothee Goffin
Citations
May 22, 2019·Environmental Science and Pollution Research International·Madan Kumar MandalNeha Chaurasia
Jan 24, 2020·Biotechnology for Biofuels·Ramachandran Sivaramakrishnan, Aran Incharoensakdi
Nov 23, 2017·ChemSusChem·Arun K VuppaladadiyamMing Zhao
Oct 27, 2018·Bioresource Technology·Ramachandran SivaramakrishnanAran Incharoensakdi
Dec 29, 2020·Chemosphere·Sivagnanam SilambarasanNguyen Thuy Lan Chi
Feb 14, 2021·Molecules : a Journal of Synthetic Chemistry and Natural Product Chemistry·Vimala BalasubramaniamMohd Fairulnizal Mohd Noh
Oct 23, 2020·International Journal of Preventive Medicine·Jia-Ping Wu
Apr 11, 2021·Chemosphere·Pengtao GaoMengchun Gao
May 10, 2021·Chemosphere·Sivagnanam SilambarasanPablo Cornejo
Jul 20, 2021·Biotechnology Reports·Ramachandran SivaramakrishnanAran Incharoensakdi
Jul 27, 2021·Journal of Environmental Management·Yanan SongRunzhi Li