丁酸梭菌NE95对果皮废料进行黑暗发酵产氢的数学模型

Mathematical modeling of biohydrogen production via dark fermentation of fruit peel wastes by Clostridium butyricum NE95.

作者信息

Elerakey Norhan, Rasmey Abdel-Hamied M, Aboseidah Akram A, Hawary Heba

机构信息

Department of Botany and Microbiology, Faculty of Science, Suez University, P.O. Box 43221, Suez, Egypt.

出版信息

BMC Biotechnol. 2024 Dec 18;24(1):105. doi: 10.1186/s12896-024-00925-7.

DOI:10.1186/s12896-024-00925-7

PMID:39695505

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11653998/

Abstract

BACKGROUND

Biohydrogen production from agro-industrial wastes through dark fermentation offers several advantages including eco-friendliness, sustainability, and the simplicity of the process. This study aimed to produce biohydrogen from fruit and vegetable peel wastes (FVPWs) by anaerobic fermentative bacteria isolated from domestic wastewater. Kinetic analysis of the produced biohydrogen by five isolates on a glucose medium was analyzed using a modified Gompertz model (MGM). Besides, the feasibility of hydrogen production by Clostridium butyricum NE95 using FVPWs as substrates was investigated.

RESULTS

The bacterial isolate NE95 was selected as the highest biohydrogen producer with maximum biohydrogen production (H) of 1617.67 ± 3.84 mL/L, R (MGM) of 870.77 mL/L/h and lag phase (λ) of 28.37 h. NE95 was phenotypically and genetically identified as C. butyricum and its 16 S rRNA gene sequence was deposited in the GenBank under the accession number PP581833. The genetic screening of hydrogenase gene clusters indicated the presence of Fe-Fe hydrogenase gene in C. butyricum NE95. C. butyricum NE95 showed the ability to produce biohydrogen from different FVPWs, with watermelon and melon peels being the most promising feedstocks for fermentation. It was revealed that using a mixture (1:1, w/w) of watermelon and melon peels as a substrate for C. butyricum NE95 significantly increased biohydrogen yield with H of 991.00 ± 10.54 mL/L, R of 236.31 mL/L/h, λ of 33.92 h and a high accuracy of R (0.997).

CONCLUSIONS

The study highlights the effectiveness of C. butyricum NE95 on the valorization of FVPWs and generates a sustainable source of biohydrogen production.

摘要

背景

通过黑暗发酵从农业工业废弃物中生产生物氢具有诸多优势，包括生态友好、可持续以及工艺简单。本研究旨在利用从生活污水中分离出的厌氧发酵细菌，从果蔬皮废弃物（FVPWs）中生产生物氢。使用改良的戈姆珀茨模型（MGM）分析了五种分离株在葡萄糖培养基上产生的生物氢的动力学。此外，还研究了丁酸梭菌NE95以FVPWs为底物生产氢气的可行性。

结果

细菌分离株NE95被选为最高生物氢生产者，最大生物氢产量（H）为1617.67±3.84 mL/L，MGM的R为870.77 mL/L/h，延迟期（λ）为28.37小时。NE95在表型和基因上被鉴定为丁酸梭菌，其16S rRNA基因序列已存入GenBank，登录号为PP581833。氢化酶基因簇的基因筛选表明丁酸梭菌NE95中存在Fe-Fe氢化酶基因。丁酸梭菌NE95显示出从不同FVPWs中生产生物氢的能力，西瓜皮和甜瓜皮是最有前景的发酵原料。结果表明，使用西瓜皮和甜瓜皮的混合物（1:1，w/w）作为丁酸梭菌NE95的底物可显著提高生物氢产量，H为991.00±10.54 mL/L，R为236.31 mL/L/h，λ为33.92小时，R的准确度较高（0.997）。

结论

该研究突出了丁酸梭菌NE95在FVPWs增值方面的有效性，并产生了可持续的生物氢生产来源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dfec/11653998/3cdd8a725b91/12896_2024_925_Fig1_HTML.jpg

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丁酸梭菌NE95对果皮废料进行黑暗发酵产氢的数学模型

Mathematical modeling of biohydrogen production via dark fermentation of fruit peel wastes by Clostridium butyricum NE95.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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