The stability of ethanol production from organic waste by a mixed culture depends on inoculum transfer time

Carrillo-Barragán, Priscilla, Dolfing, Jan, Sallis, Paul and Gray, Neil (2021) The stability of ethanol production from organic waste by a mixed culture depends on inoculum transfer time. Biochemical Engineering Journal, 166. p. 107875. ISSN 1369-703X

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Mixed Culture Fermentation is a promising route for bioethanol production from organic wastes. Yet, achieving a stable ethanologenic activity in undefined mixed cultures remains a challenge. This work aimed to retain ethanol production from organic municipal solid waste by microbial communities enriched from sheep rumen and anaerobic sludge mixtures, under low process control (initially aerobic conditions and initial pH ≤ 5.5). To find a stable operating window, sequential inoculum transfer intervals were evaluated (14 and 3-days). Soluble fermentation product profiles and changes in the prokaryotic communities were monitored. The originally inoculated batches always produced high ethanol concentrations (60 mM; 0.070 LEtOH/Kgwaste), equivalent to 1/6 of the current corn grain-based ethanol industrial production process. Fermentative activity and community richness significantly decreased in both transfer times regimes tested. However, the 3-day transfer interval led to a stable community which consistently produced ethanol (30 mM) as its main soluble fermentation product. Originally inoculated and 3-day transferred communities consistently enriched for a solventogenic Clostridium and an acid-tolerant Pseudomonas species. Ethanologenesis, as a dominant catabolic process, is an inherent property of these mixed culture fermentations, and its maintenance across successive transfers is critically dependant on the inoculum transfer time.

Item Type: Article
Uncontrolled Keywords: Bioethanol, Mixed Culture Fermentation, Organic waste, Microbial community, Environmental biotechnology, Waste valorisation
Subjects: H100 General Engineering
Department: Faculties > Engineering and Environment > Mechanical and Construction Engineering
Depositing User: Ellen Cole
Date Deposited: 15 Dec 2020 12:28
Last Modified: 28 Nov 2021 03:30

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