The authors would like to thank K.E. Skóra from the Hel Marine Station of the Institute of Oceanography (University of Gdańsk) for providing laboratory space and assistance of Marine Station staff and to A. Zgrundo from the Institute of Oceanography (University
of Gdańsk) for facilitating microphotography of histological slides. This study was financially supported by the National Science Centre (grant nos. N N304 260740 and DEC-2012/05/N/NZ8/00739) and the Institute of Oceanology of the Polish Academy of Sciences (funds for Ph.D. students 2011–2012). “
“Energy is the most essential requirement for human INK 128 cost survival. The complete dependence of mankind on fossil fuels may cause a major shortage in
the future. Biofuels made from bio-products reduce the need for petroleum oil and offer considerable benefits for sustainability and reduce pollutant and greenhouse gas emissions (Hansen et al., 2009). Of the biofuels, biodiesel is highly promising. The main advantages of using biodiesel Galunisertib are that it is renewable, non-toxic, and biodegradable and can be used without modifying existing engines because it possesses similar properties to diesel fuel and produces less harmful gas emissions, such as sulphur oxide (Agarwal, 2007 and Hansen et al., 2009). Biodiesel reduces net carbon dioxide emissions by 78% on a lifecycle basis compared to conventional diesel fuel (Gunvachai et al., 2007). Biodiesel consists of fatty acid methyl esters prepared from triglycerides by transesterification with methanol (Gerpen, 2005). During transesterification, the glycerides in fats or oils react with an alcohol in the presence of a catalyst (Banerjee and Chakraborty, 2009, Enweremadu and Mbarawa, 2009 and Zabeti et al., 2009) and are converted into monoesters,
yielding free glycerol as a by-product. Biodiesel can be produced from different feedstocks. Each originating oil or fat is characterised by a different fatty acid composition, and the final ester properties differ significantly based on the feedstock, alcohol used in the esterification and the exact chemical process followed Montelukast Sodium (Knothe, 2005). Recently, much research has focused on the production of biodiesel from non-edible sources, such as Jatropha and algae ( Komninos and Rakopoulos, 2012 and Pinzi et al., 2009). There has been increased interest in the marine production of biofuels derived from macro-algae (seaweed) and microalgae (single cell plants) ( Singh and Cu, 2010 and Williams and Laurens, 2010). Biodiesels derived from micro- and macro-algae have become known as one of the most encouraged unusual sources of lipids for use in biodiesel production because they are renewable in nature, can be produced on a large scale and are environmentally friendly ( Carvalho et al., 2011).