Biocatalysis of triglycerides transesterification using fungal biomass: a biorefinery approach.

Q1 Agricultural and Biological Sciences Fungal Biology and Biotechnology Pub Date : 2023-06-12 DOI:10.1186/s40694-023-00160-3
Nadeem I Elhussiny, Ahmed M A Mohamed, Heba A El-Refai, Sayeda S Mohamed, Yousseria M Shetaia, Hala A Amin, Gerd Klöck
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Abstract

Background: The use of microbial biomasses, such as fungal biomass, to catalyze the transesterification of triglycerides (TG) for biodiesel production provides a sustainable, economical alternative while still having the main advantages of expensive immobilized enzymes.

Results: Biomasses of Aspergillus flavus and Rhizopus stolonifera were used to catalyze the transesterification of TG in waste frying oil (WFO). Isopropanol as an acyl-acceptor reduced the catalytic capability of the biomasses, while methanol was the most potent acyl-acceptor with a final fatty acid methyl ester (FAME) concentration of 85.5 and 89.7%, w/w, for R. stolonifer and A. flavus, respectively. Different mixtures of the fungal biomasses were tested, and higher proportions of A. flavus biomass improved the mixture's catalytic capability. C. sorokiniana cultivated in synthetic wastewater was used as feedstock to cultivate A. flavus. The biomass produced had the same catalytic capability as the biomass produced in the control culture medium. Response surface methodology (RSM) was adopted using central composite design (CCD) to optimize the A. flavus biomass catalytic transesterification reaction, where temperature, methanol concentration, and biomass concentration were selected for optimization. The significance of the model was verified, and the suggested optimum reaction conditions were 25.5 °C, 250 RPM agitation with 14%, w/w, biomass, 3 mol/L methanol, and a reaction duration of 24 h. The suggested optimum conditions were tested to validate the model and a final FAME concentration of 95.53%. w/w was detected.

Conclusion: Biomasses cocktails might be a legitimate possibility to provide a cheaper technical solution for industrial applications than immobilized enzymes. The use of fungal biomass cultivated on the microalgae recovered from wastewater treatment for the catalysis of transesterification reaction provides an additional piece of the puzzle of biorefinery. Optimizing the transesterification reaction led to a valid prediction model with a final FAME concentration of 95.53%, w/w.

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利用真菌生物量进行甘油三酯酯交换的生物催化:一种生物炼制方法。
背景:利用微生物生物量,如真菌生物量,催化甘油三酯(TG)的酯交换反应生产生物柴油提供了一个可持续的,经济的替代方案,同时仍然具有昂贵的固定化酶的主要优点。结果:利用黄曲霉和匍匐茎霉的生物质催化废煎炸油中TG的酯交换反应。异丙醇作为酰基受体降低了生物质的催化能力,而甲醇是最有效的酰基受体,对匍匐茎和黄茎的最终脂肪酸甲酯(FAME)浓度分别为85.5%和89.7%,w/w。对不同真菌生物量的混合物进行了测试,黄曲霉生物量的比例越高,混合物的催化能力越强。以在合成废水中培养的sorokiniana为原料,培养黄曲霉。所产生的生物质与对照培养基中产生的生物质具有相同的催化能力。采用响应面法(RSM),以温度、甲醇浓度和生物量浓度为优化条件,采用中心复合设计(CCD)对黄芪生物质催化酯交换反应进行优化。结果表明,最佳反应条件为25.5°C, 250 RPM搅拌,14%,w/w,生物质,3 mol/L甲醇,反应时间为24 h。对该模型进行了验证,最终FAME浓度为95.53%。W / W被检测。结论:与固定化酶相比,生物质鸡尾酒可能为工业应用提供更便宜的技术解决方案。利用从废水处理中回收的微藻培养的真菌生物量来催化酯交换反应,为生物炼制提供了另一个难题。通过对酯交换反应的优化,得到了一个有效的预测模型,最终的FAME浓度为95.53%,w/w。
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来源期刊
Fungal Biology and Biotechnology
Fungal Biology and Biotechnology Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
10.20
自引率
0.00%
发文量
17
审稿时长
9 weeks
期刊最新文献
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