TY - JOUR
T1 - Methanotroph biotransformation for nutrient recovery
T2 - a review of current strategies and future opportunities
AU - Zheng, Xin
AU - Liu, Qianru
AU - Khademi, Sahar
AU - Khoshnevisan, Benyamin
AU - Xu, Mingyi
AU - Zhang, Yifeng
AU - Lou, Yu
AU - Liu, Hongbin
AU - Duan, Na
N1 - Publisher Copyright:
© 2024, Alpha Creation Enterprise. All rights reserved.
PY - 2024/6
Y1 - 2024/6
N2 - The escalating global demand for protein and the imperative to meet sustainable development goals have driven the emergence of biotransformation platforms, with methanotrophs showing significant potential in this field. In this paper, the metabolism, nutritional requirements, cultivation strategies, and bioreactors of methanotrophs are reviewed. Integrating upstream and downstream technologies is also advocated to advance the development of methanotroph biotransformation platforms toward a circular economy model. The advancements in utilizing biogas as a viable carbon source and wastewater as a nitrogen source are discussed, emphasizing the need for detailed quality control and safety assessments to ensure the suitability of single-cell protein as animal feed. In general, by integrating advanced nutrient recovery technologies to define new process routes, methanotroph biotransformation platforms can bring better environmental benefits by reducing carbon emissions and saving resources. Shifting to renewable energy is crucial for achieving environmental sustainability. By using renewable energy to power microbial fermentation, biomass dehydration, and waste recycling, the platform can offset high energy consumption and attain significant market competitiveness with traditional protein sources.
AB - The escalating global demand for protein and the imperative to meet sustainable development goals have driven the emergence of biotransformation platforms, with methanotrophs showing significant potential in this field. In this paper, the metabolism, nutritional requirements, cultivation strategies, and bioreactors of methanotrophs are reviewed. Integrating upstream and downstream technologies is also advocated to advance the development of methanotroph biotransformation platforms toward a circular economy model. The advancements in utilizing biogas as a viable carbon source and wastewater as a nitrogen source are discussed, emphasizing the need for detailed quality control and safety assessments to ensure the suitability of single-cell protein as animal feed. In general, by integrating advanced nutrient recovery technologies to define new process routes, methanotroph biotransformation platforms can bring better environmental benefits by reducing carbon emissions and saving resources. Shifting to renewable energy is crucial for achieving environmental sustainability. By using renewable energy to power microbial fermentation, biomass dehydration, and waste recycling, the platform can offset high energy consumption and attain significant market competitiveness with traditional protein sources.
KW - Carbon recovery
KW - Environmental benefit
KW - Methanotroph
KW - Nutrient recovery
KW - Single-cell protein
KW - Sustainability
U2 - 10.18331/BRJ2024.11.2.2
DO - 10.18331/BRJ2024.11.2.2
M3 - Journal article
AN - SCOPUS:85200670325
SN - 2292-8782
VL - 11
SP - 2065
EP - 2081
JO - Biofuel Research Journal
JF - Biofuel Research Journal
IS - 2
ER -