Syntrophy between bacteria and archaea enhances methane production in an EGSB bioreactor fed by cheese whey wastewater

IF 3.7 2区 农林科学 Q2 FOOD SCIENCE & TECHNOLOGY Frontiers in Sustainable Food Systems Pub Date : 2023-12-22 DOI:10.3389/fsufs.2023.1244691
María Emperatriz Domínguez-Espinosa, Abumalé Cruz-Salomón, J. A. Ramírez De León, Jesús Mauricio Ernesto Hernández-Méndez, M. G. Santiago-Martínez
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Abstract

The cheese-making process generates large amounts of cheese whey wastewater (CWW), which is abundant in nutrients but difficult to dispose of, contributing to the eutrophication of natural environments due to inadequate waste management. Here we show the anaerobic digestion of CCW by syntrophy between bacteria and archaea in an expanded granular sludge bed (EGSB) bioreactor as a low-cost alternative for bioremediation and biofuel production. The performance of the EGSB bioreactor and the composition of the natural microbial community were evaluated. During the operation of the EGSB bioreactor, physicochemical parameters such as alkalinity ratio (0.25), pH (7.5), and temperature (26°C) were attained and maintained, as well as light- and oxygen-free conditions, which favored the metabolism of oxygen-sensitive bacteria and methane-producing archaea (methanogens). Under these conditions, the chemical oxygen demand (COD) removal rate was highly efficient (> 89%). Methane (CH4) was produced from organic matter degradation by a few methanogens, mainly from Methanosaeta spp., and was enhanced by the metabolic interaction between bacteria and archaea. The biochemical methane potential (BMP) was >335 mL CH4/gCOD, indicating that the syntrophic microbial community is very efficient in removing organic matter and CH4 produced from CWW. Our results suggest that CWW could be treated in EGSB bioreactors and used as a sustainable alternative to CH4 production and also provide insights for the design of synthetic microbial communities (SynComs) for bioremediation, biogas production, and other biotechnological processes.
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细菌和古细菌之间的协同作用提高了以奶酪乳清废水为原料的 EGSB 生物反应器中的甲烷产量
奶酪制作过程中会产生大量奶酪乳清废水(CWW),这些废水营养丰富却难以处理,由于废物管理不当,导致自然环境富营养化。在这里,我们展示了在膨胀颗粒污泥床(EGSB)生物反应器中通过细菌和古细菌之间的合成作用对乳酪废水进行厌氧消化,作为生物修复和生物燃料生产的一种低成本替代方法。对 EGSB 生物反应器的性能和天然微生物群落的组成进行了评估。在 EGSB 生物反应器运行期间,达到并维持了碱度比(0.25)、pH 值(7.5)和温度(26°C)等理化参数,以及无光和无氧条件,这有利于氧敏感细菌和产甲烷古细菌(甲烷菌)的新陈代谢。在这些条件下,化学需氧量(COD)的去除率非常高(> 89%)。甲烷(CH4)是由少数甲烷菌(主要来自甲烷菌属 Methanosaeta spp.)降解有机物产生的,并通过细菌和古细菌之间的新陈代谢相互作用得到增强。生化甲烷潜能值(BMP)大于 335 mL CH4/gCOD,表明合成微生物群落能非常有效地去除有机物和从化武中产生的 CH4。我们的研究结果表明,化武可以在 EGSB 生物反应器中进行处理,并作为一种可持续的甲烷生产替代方法,同时也为设计用于生物修复、沼气生产和其他生物技术过程的合成微生物群落(SynComs)提供了启示。
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来源期刊
Frontiers in Sustainable Food Systems
Frontiers in Sustainable Food Systems Agricultural and Biological Sciences-Horticulture
CiteScore
5.60
自引率
6.40%
发文量
575
审稿时长
14 weeks
期刊最新文献
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