Abstract
Hydrophobic carriers can be used to improve the activity, stability and other properties of enzymes. Physical agents, like ultrasound, may also contribute to improving the dispersion and collision of the reagent molecules, decreasing the reaction time and intensifying the catalytic process. However, its effect on the enzyme activity and reaction selectivity is still not entirely understood. Here, enzyme modulation of immobilized lipases was studied under pulsed ultrasound irradiation in fatty acid ethyl ester (FAEE) synthesis for biodiesel production. Novozym 435® and two commercial lipases from Thermomyces lanuginosus and Rhizomucor miehei, immobilized on Octadecyl-Sepabeads were used as a biocatalyst in the transesterification reaction of vegetable oils and ethanol. The use of ultrasound associated with catalysis by the Novozym 435 increased the production of FAEE by about three times (from 8.9 to 26.4%) using soybean oil and changes were observed in the profile of the products. From the sonicated reaction, ethyl-palmitate production decreased from 23.4 to 11.7%, while the ethyl-linoleate content rose from 47.5 to 59.2%. On the other hand, the T. lanuginosus lipase was less affected by sonication with the overall production of FAEE increasing from 17.2 to 24.1%, with ethyl-palmitate and ethyl-linoleate content changing from 16.2 to 17.5% and 55.0 to 47.8%, respectively. Although the changes in the production yield are not too high, the main idea here was to show that ultrasound modulates the lipase activity as well as its respective selectivity. Thus, ultrasound, is responsible for changing the ethyl ester production, which can be applied to many other biochemical processes to improve or modulate their synthesis yield.
Highlights
Biodiesel is a mixture of fatty acid esters produced by a transesterification reaction between triacylglycerols from vegetable oil or animal fat with alcohol (Bouaid, El boulifi, Hahati, Martinez, & Aracil, 2014; Zhou, Chen, & Yan, 2015) and it has been investigated as a replacement for petrodiesel
The results suggest that lipases from R. miehei are more sensitive to possible structure distortion by the hydrophobic interaction with the support, since it showed low recovered activity after immobilization
The results showed the potential for TLL to be used in the production of biodiesel, converting triacylglycerol molecules into fatty acid ethyl esters
Summary
Biodiesel is a mixture of fatty acid esters produced by a transesterification reaction between triacylglycerols from vegetable oil or animal fat with alcohol (Bouaid, El boulifi, Hahati, Martinez, & Aracil, 2014; Zhou, Chen, & Yan, 2015) and it has been investigated as a replacement for petrodiesel. The transesterification of triacylglycerols catalyzed by lipases may be a method that overcomes this problem and could bring advantages over chemical catalysis (Amoah et al, 2016; Shimada et al, 1999) such as lower energy consumption and easier glycerol separation. Lipases used in this process are classified based on their regioselectivity for the position of unsaturated bonds of the triacylglycerol molecule: R1 and R3 (sn-1-3), R2 (sn-2) or nonspecific (Taher, Al-Zuhair, Al-Marzouqi, Haik, & Farid, 2011). The immobilization of enzymes is needed to decrease the process cost and to improve the enzyme characteristics, such as stability and activity
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