Co-fermentation of sugar-alcohol industry waste to produce hydrogen and value-added metabolites

Q1 Environmental Science

Bioresource Technology Reports Pub Date : 2025-07-07 DOI:10.1016/j.biteb.2025.102211

Bruna S. Dionizio , Camila A.B.S. Rabelo , Caroline V. Rodrigues , Franciele P. Camargo , Edson L. Silva , Dulce H.F. de Souza , Maria Bernadete A. Varesche

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Abstract

The research focused on optimizing hydrogen production through the co-fermentation of three sugar-alcohol industry residues, sugarcane bagasse (SCB), filter cake (FC), and sugarcane vinasse (SCV). Batch assays were performed using enzymatically pretreated SCB (23.4 g·L⁻¹) combined with varying concentrations of FC (7.9–37.7 g·L⁻¹) and SCV (8.3–31.7 g COD·L⁻¹). A mixed microbial culture bioaugmented with Clostridium butyricum was employed as the inoculum. In the process optimization the highest hydrogen yield (3239.78 mL·L⁻¹) was achieved under conditions of 33.1 g·L⁻¹ FC and 28.3 g COD·L⁻¹ SCV, along with the production of 7132.8 mg·L⁻¹ of valuable organic acids and solvents. Additionally, SCV at higher concentrations (31.7 g COD·L⁻¹) favored homoacetogenesis, leading to an acetic acid accumulation of 7526.8 mg·L⁻¹. Microbial community analysis by 16S rRNA sequencing revealed the dominance of Clostridium, Caproiciproducens, Anaerotruncus, Cellulosilyticum, and members of Lachnospiraceae, whose inferred functional genes included those encoding endoglucanase, xylanase, arabinofuranosidase, and lignin-degrading peroxidases. The findings highlight the potential of integrated bioconversion of sugar-alcohol industry residues to improve hydrogen and bioproduct generation, supporting more sustainable waste management and renewable energy production.

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糖醇工业废渣共发酵产氢及增值代谢物

研究了甘蔗甘蔗渣（SCB）、滤饼（FC）和甘蔗酒糟（SCV）三种糖醇工业废渣共发酵产氢的优化方法。采用酶解预处理的SCB （23.4 g·L−1）结合不同浓度的FC （7.9-37.7 g·L−1）和SCV （8.3-31.7 g COD·L−1）进行批量测定。采用混合丁酸梭菌培养物作为接种物。在FC为33.1 g·L−1，COD为28.3 g·L−1，SCV为28.3 g·L−1的条件下，产氢率最高，为3239.78 mL·L−1，有价有机酸和溶剂产量为7132.8 mg·L−1。此外，高浓度SCV （31.7 g COD·L−1）有利于均匀醋酸生成，导致乙酸积累量为7526.8 mg·L−1。微生物群落16S rRNA测序分析显示，Clostridium、Caproiciproducens、Anaerotruncus、Cellulosilyticum和Lachnospiraceae的成员占主导地位，推测其功能基因包括编码内切葡聚糖酶、木聚糖酶、阿拉伯糖葡聚糖酶和木质素降解过氧化物酶的基因。研究结果强调了糖酒精工业残留物综合生物转化的潜力，以改善氢气和生物产品的产生，支持更可持续的废物管理和可再生能源生产。

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