Biodiesel production with special emphasis on lipase-catalyzed transesterification

A partially purified lipase from the Pseudomonas aeruginosa strain (PSA-01) isolated from the palm oil fruit Elaeis guineensis was used as biocatalyst to produce fatty acid methyl esters (FAME). Lyophilized lipase supernatant (LLS) was used during the first step to screen the main variables (pH, temperature, stoichiometric oil:methanol ratio, water content and type of oil). Other variables which were identified during the screening assays (scale of reaction recipient, LLS amount and use of hexane to solubilize methanol forming a methanol-oil microemulsion) were tested during a second step. The response variable was % molar yield of FAME. It was quantified by GC. Additionally, the LLS work parameters were optimized and compared to a partially purified lipase (PPL) during a final assay. The first-order interactions between the analyzed factors were significant (p<0.05). The highest yield was 4.16% w/w (respect to oil) using a partially purified lipase (PPL) with pH 8, refined, bleached, and deodorized oil (RBD), 5% water (by volume) in oil and 10% hexane (by volume), and a stoichiometric ratio of 1:170 oil:methanol. The final assay was carried out at 54°C and 200 rpm for 48 hours. It resulted in a 34.68% conversion using PPL. It also showed a 13-fold improvement versus the initial yield with LLS, suggesting the need for a better purification process. During this research, the lipase was partially purified and used at an alkaline pH. It showed resistance to organic compounds such as methanol and hexane. This implies great potential to act as an effective biocatalyst in the implementation of biodiesel production processes.

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“…This might be the reason for showing different activity on different oil substrates. Thus, there is a need for optimizing the process [24].…”

Section: Discussionmentioning

confidence: 99%

Applied Biocatalysis with an Organic Resistant Partially Purified Lipase from P. aeruginosa During FAME Production

Cabrejo¹,

Barrera²,

Prieto-Correa³

2015

TOCATJ

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“…In other reports, optimum ratios of ethyl acetate to oil were 12:1 and 11:1, respectively, when various vegetable oils were used as the substrate 17,18 . In the present study, crude microalgal oil contained different kinds of complex compounds that include polar lipids wax esters, sterols and hydrocarbons such as tocopherols, carotenoids and terpenes and phytylated pyrrole derivatives such as chlorophylls 22 . Therefore, this can be considered as a -viscous substrate, and it seems that higher amounts of ethyl acetate are necessary to improve the transesterification reaction.…”

Section: Methodsmentioning

confidence: 95%

Enzymatic Production of Biodiesel from Microalgal Oil using Ethyl Acetate as an Acyl Acceptor

et al. 2015

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“…43 As lipases podem catalisar reações de hidrólise, alcoólise, acidólise, esterificação e transesterificação. 37 As lipases podem ser encontradas em tecidos de animais e plantas, podendo também ser produzidas por microorganismos. A escolha da fonte de lipases para aplicações industriais deve levar em consideração a possibilidade de utilização de mono-, di-e triglicerídeos, a utilização de ácidos graxos livres, baixa inibição pelo produto, alta atividade em meio aquoso e não-aquoso, potencial de utilização continuada, estabilidade frente a agentes distorcionantes e.g.…”

Section: Lipasesunclassified

Enzymes and Ionic Liquids: a Promising Combination Towards a Clean Biodiesel

Medeiros¹,

Gonçalves²,

Rodrigues³

et al. 2013

Revista Virtual De Química

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Abstract:The current manuscript describes the advantages of ionic liquids and lipases (enzymes) association towards a clean biodiesel. Acidic and basic catalytic processes, as their technological drawbacks are discussed herein. The main interaction between such enzymes and ionic liquids are presented for a better understanding of the improvement on the catalytic activity of lipase enzymes when these biocatalysts are supported on an ionic media. Selected examples of recent scientific literature are described to show the promising and powerful combination towards a clean biodiesel synthesis.Keywords: Biodiesel; enzymes; ionic liquids. ResumoO presente artigo descreve as vantagens decorrentes da combinação de líquidos iônicos com enzimas (lipases) visando à obtenção de um biodiesel mais limpo. São discutidos os processos catalisados por ácidos e por bases e as suas desvantagens são discutidas. As principais interações entre as enzimas e os líquidos iônicos são apresentadas para se entender o porquê de uma melhora na atividade catalítica de lipases quando estes biocatalisadores são suportados neste meio iônico. Exemplos selecionados da literatura científica atual são descritos para exemplificar o poder e a perspectiva desta combinação tão promissora para a síntese de um biodiesel limpo.Palavras-chave: Biodiesel; enzimas; líquidos iônicos.

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Biodiesel production with special emphasis on lipase-catalyzed transesterification

Cited by 112 publications

References 55 publications

Applied Biocatalysis with an Organic Resistant Partially Purified Lipase from P. aeruginosa During FAME Production

Applied Biocatalysis with an Organic Resistant Partially Purified Lipase from P. aeruginosa During FAME Production

Enzymatic Production of Biodiesel from Microalgal Oil using Ethyl Acetate as an Acyl Acceptor

Enzymes and Ionic Liquids: a Promising Combination Towards a Clean Biodiesel

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