Concomitant strain of Bacillus vallismortis BR2 and Escherichia coli Khodavandi-Alizadeh-2 for Biocatalytic Synthesis of Fatty Acid Methyl Ester from Waste Oil Feedstock

Cumhuriyet Science Journal Pub Date : 2023-06-30 DOI:10.17776/csj.1206615

M. Osho, Olayinka Mary Otolori̇n

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Abstract

Bacillus vallismortis BR2 and Escherichia coli Khodavandi-Alizadeh-2 lipases (E.C.3.1.1.3) were used to produce fatty acid methyl ester (FAME), a sustainable source of fuel. The lipase activity was measured using the titrimetric method after it was extracted from a solid fermented substrate in phosphate buffer. The use of Central Composite Design to optimize condition parameters was examined, while qualitative and quantitative assessments of FAME samples were performed using GC-MS with MSD in scan mode and selective ion monitoring. Lipase activity peaked at 24 h and then declined as the incubation time went on. The independent variables, such as pH, temperature, agitation, incubation time and enzyme quantity, all had an effect on biodiesel yield since they were all significant in the rate of biodiesel yield. FAME yield increased significantly after adding 1 to 2 mL of enzyme and a pH range of 4.57143 to 7.42857, but thereafter declined. The chromatograms indicated a peak of cis-10-Heptadecanoic acid methyl ester with concentrations of 39.95 mg/L and 58.95 mg/L in the FAME molecules. The viscosity (3.67 m3/s), specific gravity (0.813 g/cm3), flash point (102.70 °C), cetane number (55.52), and pour point (-24 °C) of the fuel were also measured. The synthesized biodiesel from the spent oil through the synergic enzymes were found to be a simple, effective, and sustainable fuel production process, as well as a potential means of eliminating pollution caused by haphazard waste cooking oil disposal.

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瓦利斯莫提斯芽孢杆菌BR2和大肠杆菌Khodavandi-Alizadeh-2的共生菌株对废油生物催化合成脂肪酸甲酯的研究

vallismortis芽孢杆菌BR2和大肠杆菌Khodavandi-Alizadeh-2脂肪酶（E.C.3.1.1.3）用于生产脂肪酸甲酯（FAME），这是一种可持续的燃料来源。在磷酸盐缓冲液中从固体发酵底物中提取脂肪酶后，使用滴定法测量脂肪酶活性。检查了使用中央复合设计优化条件参数，同时使用扫描模式下的GC-MS和MSD以及选择性离子监测对FAME样品进行定性和定量评估。脂肪酶活性在24 h达到峰值，然后随着培养时间的延长而下降。pH、温度、搅拌、培养时间和酶量等自变量对生物柴油产量都有影响，因为它们对生物柴油的产量都有显著影响。在添加1至2 mL酶和4.57143至7.42857的pH范围后，FAME产量显著增加，但此后下降。色谱图显示在FAME分子中浓度为39.95 mg/L和58.95 mg/L的顺式-10-十七烷酸甲酯的峰。还测量了燃料的粘度（3.67 m3/s）、比重（0.813 g/cm3）、闪点（102.70°C）、十六烷值（55.52）和倾点（-24°C）。从废油中通过协同酶合成生物柴油是一种简单、有效、可持续的燃料生产工艺，也是消除随意废弃食用油污染的潜在手段。

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Cumhuriyet Science Journal

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审稿时长

10 weeks