Supplementation with electrically conductive materials unlocks lactic acid conversion into volatile fatty acids during cheese whey fermentation

IF 7.4 2区工程技术 Q1 ENGINEERING, CHEMICAL

Journal of Environmental Chemical Engineering Pub Date : 2025-05-22 DOI:10.1016/j.jece.2025.117197

Cecilia Petitta , Matteo Tucci , Matteo Daghio , Chiara Capelli , Carlo Viti , Alessandra Adessi , Luca di Palma , Carolina Cruz Viggi , Federico Aulenta

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引用次数: 0

Abstract

Cheese whey (CW), a by-product of the dairy industry, poses environmental challenges due to its high organic load and substantial production volumes. Dark fermentation (DF) offers a promising biological approach to valorizing CW by converting its carbohydrate-rich organic matter into valuable products such as organic acids, alcohols, and hydrogen. This study investigated the application of electrically conductive materials (ECMs)—specifically magnetite, biochar, and graphite—to enhance CW fermentation and increase the production of high-value volatile fatty acids (VFAs). Batch fermentation experiments revealed that incorporating ECMs significantly influenced the DF process. Notably, VFA production, particularly propionic acid, was markedly enhanced. In unamended control microcosms, CW fermentation led to an almost complete conversion of carbohydrates into lactic acid. Among the ECMs tested, magnetite had the greatest impact, increasing total VFA concentrations to 45.3 ± 5.9 g COD/L—a 22.5-fold improvement over the control. The addition of ECMs promoted the growth and enrichment of microorganisms capable of lactic acid reduction into propionic acid, such as Clostridiaceae and Propionibacteraceae, while also altering the microbial community and electron flow dynamics. This resulted in a significant increase in acetic acid production, which was over five times higher in ECM-amended treatments compared to controls. ECMs likely facilitated the disposal of excess reducing power, possibly via direct interspecies electron transfer (DIET), which further enhanced lactic acid conversion to propionic acid. From an environmental perspective, this study offers a sustainable solution for managing CW, reducing its environmental impact by converting it into valuable biochemicals. From an industrial standpoint, the enhanced production of VFAs, particularly propionic and acetic acids, presents a pathway to generate precursors for bio-based polymers, food additives, and other high-value applications.

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在奶酪乳清发酵过程中，补充导电材料可以使乳酸转化为挥发性脂肪酸

奶酪乳清（CW）是乳制品行业的副产品，由于其高有机负荷和大量产量，对环境构成了挑战。暗发酵（DF）通过将富含碳水化合物的有机物转化为有机酸、醇和氢等有价值的产品，提供了一种很有前途的生物途径。本研究探讨了导电材料（ecm）的应用，特别是磁铁矿、生物炭和石墨，以增强连续发酵和增加高价值挥发性脂肪酸（VFAs）的产量。分批发酵实验表明，加入ECMs对发酵过程有显著影响。值得注意的是，VFA的产量，特别是丙酸的产量明显增加。在未经修改的控制微观环境中，连续发酵导致碳水化合物几乎完全转化为乳酸。在测试的ecm中，磁铁矿的影响最大，使总VFA浓度增加到45.3 ± 5.9 g COD/ l -比对照组提高了22.5倍。ECMs的添加促进了Clostridiaceae和Propionibacteraceae等能够将乳酸还原为丙酸的微生物的生长和富集，同时也改变了微生物群落和电子流动力学。这导致乙酸产量显著增加，与对照组相比，经ecm处理的乙酸产量高出5倍以上。ecm可能通过直接种间电子转移（DIET）促进了多余还原力的处理，进一步促进了乳酸向丙酸的转化。从环境的角度来看，本研究为管理化学武器提供了一个可持续的解决方案，通过将其转化为有价值的生化物质来减少其对环境的影响。从工业角度来看，VFAs，特别是丙酸和乙酸的产量增加，为生物基聚合物、食品添加剂和其他高价值应用的前体生产提供了一条途径。

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来源期刊

Journal of Environmental Chemical Engineering Environmental Science-Pollution

CiteScore

11.40

自引率

6.50%

发文量

2017

审稿时长

27 days

期刊介绍： The Journal of Environmental Chemical Engineering (JECE) serves as a platform for the dissemination of original and innovative research focusing on the advancement of environmentally-friendly, sustainable technologies. JECE emphasizes the transition towards a carbon-neutral circular economy and a self-sufficient bio-based economy. Topics covered include soil, water, wastewater, and air decontamination; pollution monitoring, prevention, and control; advanced analytics, sensors, impact and risk assessment methodologies in environmental chemical engineering; resource recovery (water, nutrients, materials, energy); industrial ecology; valorization of waste streams; waste management (including e-waste); climate-water-energy-food nexus; novel materials for environmental, chemical, and energy applications; sustainability and environmental safety; water digitalization, water data science, and machine learning; process integration and intensification; recent developments in green chemistry for synthesis, catalysis, and energy; and original research on contaminants of emerging concern, persistent chemicals, and priority substances, including microplastics, nanoplastics, nanomaterials, micropollutants, antimicrobial resistance genes, and emerging pathogens (viruses, bacteria, parasites) of environmental significance.