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Single-cell protein production from CO2 and electricity with a recirculating anaerobic-aerobic bioprocess

Zeyan Pan, Yuhan Guo, Weihe Rong, Sheng Wang, Kai Cui, Wenfang Cai, Zhihui Shi, Xiaona Hu, Guokun Wang, Kun Guo

2025Environmental Science and Ecotechnology15 citationsDOIOpen Access PDF

Abstract

Microbial electrosynthesis (MES) represents a promising approach for converting CO 2 into organic chemicals. However, its industrial application is hindered by low-value products, such as acetate and methane, and insufficient productivity. To address these limitations, coupling acetate production via MES with microbial upgrading to higher-value compounds offers a viable solution. Here we show an integrated reactor that recirculates a cell-free medium between an MES reactor, hosting anaerobic homoacetogens ( Acetobacterium ), and a continuously stirred tank bioreactor, hosting aerobic acetate-utilizing bacteria ( Alcaligenes ), for efficient single-cell protein (SCP) production from CO₂ and electricity. The reactor achieved a maximum cell dry weight (CDW) of 17.4 g L -1 , with an average production rate of 1.5 g L -1 d -1 . The protein content of the biomass reached 74% of the dry weight. Moreover, the integrated design significantly reduced wastewater generation, mitigated product inhibition, and enhanced SCP production. These results demonstrate the potential of this integrated reactor for the efficient and sustainable production of high-value bioproducts from CO 2 and electricity using acetate as a key intermediate. • A hybrid bioreactor integrating anaerobic and aerobic processes is developed for converting electricity into single-cell protein (SCP). • The system facilitates collaboration between anaerobic Acetobacterium and aerobic Alcaligenes. • Efficient SCP production from CO 2 is achieved using acetate as the intermediate metabolite. • The reactor design mitigates product inhibition, reduces base consumption, and minimizes wastewater generation.

Topics & Concepts

BioprocessAnaerobic exerciseProduction (economics)Biochemical engineeringProcess engineeringEnvironmental sciencePulp and paper industryChemistryEngineeringBiologyChemical engineeringEconomicsMacroeconomicsPhysiologyMicrobial Fuel Cells and BioremediationCO2 Reduction Techniques and CatalystsMicrobial metabolism and enzyme function
Single-cell protein production from CO2 and electricity with a recirculating anaerobic-aerobic bioprocess | Litcius