Use of plant lipases from seeds for enzymatic catalysis of ethyl esters of vegetable oils for the production of biodiesel

Les lipases présentent un grand intérêt pour la synthèse du Biodiesel, carburant alternatif au gasoil, généralement obtenu d’une transestérification des triacylglycérols avec un alcool, la plupart du temps le méthanol. Pour avoir un ester issu totalement de la biomasse végétale, l’éthanol peut être utilisé comme accepteur d’acyle. L’objectif de cette étude est de développer des procédés enzymatiques de synthèses d’esters éthyliques catalysés par les lipases végétales sous leur forme brute avec des intrants (huile et alcool) d’origine végétale. D’abord, elle a consisté à la mise en évidence d’une activité lipasique pour des réactions d’éthanolyse et d’hydrolyse par les graines d’A. suarezensis, d’A. grandidieri, de J. curcas, de J. mahafalensis, de M. oleifera et de M. drouhardii. Ensuite, les influences de certains facteurs sur la capacité des extraits le(s) plus actif(s) à réaliser des réactions d’éthanolyse en milieux non aqueux, aqueux et en utilisant comme substrat leurs lipides natifs ont été étudiées. Enfin, des essais de combustion ont été menés sur un moteur monocylindre à injection directe pour l’étude des performances, des émissions et de la combustion du biodiesel produit et de ses mélanges avec le gasoil. Toutes les graines germées sont dotées d’une activité en hydrolyse et éthanolyse. La poudre d’A. grandidieri est la plus active en éthanolyse. Avec cette dernière, deux procédés ont pu être développés : un en milieu non aqueux et un en milieu aqueux (respectivement un rendement de 96,2 % et 96,3 %). Elle est aussi capable de transformer ses lipides natifs sans extraction au préalable en esters éthyliques (rendement de 91,6%). Les performances et la combustion du biodiesel et de ses mélanges sont similaires à celle du gasoil. Une réduction significative des émissions de CO, NOX, CO2 et SO2 au cours de la combustion du biodiesel et de ses mélanges est observée. Ces résultats montrent que les lipases végétales exploitées sous leurs formes brutes peuvent être une alternative aux lipases microbiennes et aux catalyseurs chimiques.There is a great interest in the use of lipase in the production of Biodiesel, alternative diesel fuel, usually obtained from a transesterification of triacylglycerol with an alcohol which is mostly methanol. To have a biodiesel derived totally from vegetable biomass, ethanol must be explored as acyl acceptor. The objective of this work is to develop enzymatic processes for the synthesis of ethyl esters catalyzed by plant lipases in their crude form with all inputs (oil and alcohol) of origin plant. Firstly, the hydrolysis and ethanolysis activities of A. suarezensis, A. grandidieri, J. curcas, J. mahafalensis, M. oleifera and M. drouhardii seeds were assessed. Subsequently, the most active(s) plant lipase(s) was selected to study the effects of some factors on their ability to carry out ethanolysis reactions in nonaqueous, aqueous media and using as substrate their lipids. Finally, combustion tests were carried out on a single cylinder direct injection engine to study the performance, emissions and combustion of biodiesel and its mixture with diesel. All germinated seeds have hydrolysis and ethanolysis activity. The most active in ethanolysis is the powder from A. grandidieri seed. With this powder, two processes were developed: one in nonaquous medium and the other in aqueous medium (yield of 96.2 % and 96.3 %, respectively). Lipase from A. grandidieri seed is able to transesterify its oils without an extraction thereof into ethyl ester. Performance and combustion characteristics of biodiesel and its mixtures are similar to that of diesel fuel. A significant reduction in CO, NOX, CO2 and SO2 emissions during the combustion of biodiesel and its mixtures is observed. These results show that plant lipases exploited in their crude form can be an alternative to microbial lipases and chemical catalysts

Lipase Activity of Tropical Oilseed Plants for Ethyl Biodiesel Synthesis and Their Typo- and Regioselectivity

The aim of this work was to investigate lipase activities in crude extracts from Adansonia suarezensis, Adansonia grandidieri, Moringa drouhardii, Moringa oleifera, Jatropha mahafalensis, and Jatropha curcas seeds in ethanolysis and hydrolysis reactions. All crude extracts from germinated seeds showed both ethanolysis and hydrolysis activities. The influence of germination, the delipidation procedure, and the triacylglycerol/ethanol molar ratio on their ethanolysis activity was studied. Crude extracts of Jatropha and Adansonia seeds showed optimal activity at pH 8 with an optimum temperature of 30 and 40 degrees C, respectively. The study of the regioselectivity of crude extracts from J. mahafalensis and A. grandidieri seeds,,which had the most active hydrolysis reaction, showed 1,3 regioselectivity in the hydrolysis reaction of vegetable oils. The crude extract from A. grandidieri seeds showed no typoselectivity, whereas the typoselectivity of the crude extract of J. mahafalensis seeds depended on the type of reaction

Solvent-Free Biodiesel Production Catalyzed by Crude Lipase Powder from Seeds: Effects of Alcohol Polarity, Glycerol, and Thermodynamic Water Activity

The aim of this work was to evaluate the potential of crude lipase powders made from Adansonia grandidieri and Jatropha mahafalensis seeds for the synthesis of fatty acid alkyl esters in a solvent-free system. The influence of the nature of the alcohol, the amount of glycerol, and hydration of the powder was investigated. Results showed that the activity of these crude lipase powders was inversely proportional to the alcohol polarity and the amount of the glycerol in the reaction medium. To ensure optimum activity, A. grandidieri and J. mahafalensis powders must be conditioned to a water activity of 0.33 and 0.66. To obtain a fatty acid ethyl ester yield greater than 95% with A. grandidieri, ethanol should be introduced at an amount corresponding to a triacylglycerol to ethanol molar ratio of 2:1 every 15 h for 96 h and use 25% of preconditioned crude lipase powders (2 additions of 12.5%)

Building TiO2-doped magnetic biochars from Citrus sinensis peels as low-cost materials for improved dye degradation using a mathematical approach

TiO2-doped ferromagnetic (TiFeBC) composites were synthesised from lignocellulosic orange peel biochar (BC) material using co-precipitation method. Several characterization techniques (XRD, SEM, EDX, FT-IR, EIS and N2 adsorption-desorption) were used to confirm the presence of Fe3O4 and TiO2 particles impregnated within the carbonaceous matrix of the biochar. Electrochemical impedance spectroscopy revealed that the sample obtained using 2.5 wt. % of TiO2 (TiFeBC1) has the lowest charge transfer resistance compared to those of 5 wt.% and 7.5 wt.%. TiFeBC1 was used for the optimization of the degradation of reactive yellow-145 from Cameroon Textile Industry using Fenton process. Optimum operational parameters were found to be: pH of 2.02, initial dye concentration of 75 mg/L, mass of material of 5998 mg/L and a time of 16.01 min. Using the CCD of the Response Surface Methodology, a predicted optimum response of 98.89 % was obtained in agreement with an experimental response of 97.95 % of dye degradation. Analysis of variance presented good correlation between the experimental data and the postulated model (R2 = 94.24 % and R2adjusted = 87.52 %). The degradation reaction was found to obey the first order kinetic rate law (R2 = 0.986) with respect to the dye. The study of interfering processes revealed that adsorption and H2O2/daylight-assisted degradation are two phenomenon that could possibly contribute to a negligible extent to the elimination of the dye during the Fenton process. The stability and efficiency of TiFeBC1 was evaluated over ten cycles and the material was found to lose approximately 5 % of its efficiency