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Scale-Up of Dark Fermentative Biohydrogen Production by Artificial Microbial Co-Cultures

İpek Ergal, Elisa H. Zech, Nikola Hanišáková, Ivan Kushkevych, Werner Fuchs, Tomáš Vítěz, Monika Vítězová, Günther Bochmann, Simon K.‐M. R. Rittmann

2022Applied Microbiology12 citationsDOIOpen Access PDF

Abstract

As a renewable energy carrier, dark fermentative biohydrogen (H2) represents a promising future alternative to fossil fuels. Recently, the limited H2 yield of 4 moles of H2 per mole glucose, the so-called “Thauer limit”, was surpassed by a defined artificial consortium. In this article, we demonstrate the upscaling of this drawing board design, from serum bottles to laboratory scale bioreactors. Our results illustrate that this designed microbial co-culture can be successfully implemented in batch mode, with maximum H2 yields of 6.18 and 4.45 mol mol−1 substrate. Furthermore, we report volumetric H2 productivities of 105.6 and 80.8 mmol H2 L−1 h−1. These rates are higher than for any other dark fermentative H2 production system using a synthetic microbial co-culture applied in batch mode on a defined medium. Our study is an important step forward for the application of artificial microbial consortia in future biotechnology and energy production systems.

Topics & Concepts

BiohydrogenDark fermentationMicrobial consortiumYield (engineering)Biochemical engineeringBioreactorFermentative hydrogen productionPulp and paper industryBiotechnologyFossil fuelMicrobial fuel cellRenewable energyEnvironmental scienceChemistryHydrogen productionBiologyEngineeringMaterials scienceHydrogenMicroorganismBacteriaEcologyOrganic chemistryMetallurgyPhysical chemistryGeneticsAnodeElectrodeAnaerobic Digestion and Biogas ProductionMicrobial Metabolic Engineering and BioproductionBiofuel production and bioconversion
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