Prospects for engineering Ralstonia eutropha and Zymomonas mobilis for the autotrophic production of 2,3-butanediol from CO2 and H2

“…In addition, technologies such as solar-driven electrolysis (Schmidt et al, 2017), supercritical water (scH 2 O) gasification (Okolie et al, 2019), and biomass pyrolysis-gasification (Dou et al, 2019) further enable the sustainable production of molecular hydrogen (H 2 ). Together, these technologies will undoubtedly enable the utilization of the reducing power of H 2 for the in vivo biosynthesis of chemicals and facilitate downstream scale-up (Wei et al, 2023). In this context, the conversion of syngas to acetate, ethanol, and other chemicals has been an active area of research in the past several decades.…”

Continuous multimodal technologies in industrial microbiology: potential for achieving high process performance and agility

“…In addition, technologies such as solar-driven electrolysis (Schmidt et al, 2017), supercritical water (scH 2 O) gasification (Okolie et al, 2019), and biomass pyrolysis-gasification (Dou et al, 2019) further enable the sustainable production of molecular hydrogen (H 2 ). Together, these technologies will undoubtedly enable the utilization of the reducing power of H 2 for the in vivo biosynthesis of chemicals and facilitate downstream scale-up (Wei et al, 2023). In this context, the conversion of syngas to acetate, ethanol, and other chemicals has been an active area of research in the past several decades.…”

Continuous multimodal technologies in industrial microbiology: potential for achieving high process performance and agility

Gas fermentation combined with water electrolysis for production of polyhydroxyalkanoate copolymer from carbon dioxide by engineered Ralstonia eutropha

Advances and challenges in bio-based 2,3-BD downstream purification: A comprehensive review