Towards closed carbon loop fermentations: Cofeeding of Yarrowia lipolytica with glucose and formic acid

Wouter A. van Winden; Robert Mans; Stefaan Breestraat; Rob A.J. Verlinden; Álvaro Mielgo-Gómez; Erik A.F. de Hulster; Hans M.C.J. de Bruijn; Henk J. Noorman

doi:10.1002/bit.28115

Towards closed carbon loop fermentations: Cofeeding of Yarrowia lipolytica with glucose and formic acid

Wouter A. van Winden, Robert Mans^*, Stefaan Breestraat, Rob A.J. Verlinden, Álvaro Mielgo-Gómez, Erik A.F. de Hulster, Hans M.C.J. de Bruijn, Henk J. Noorman

^*Corresponding author for this work

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Abstract

A novel fermentation process was developed in which renewable electricity is indirectly used as an energy source in fermentation, synergistically decreasing both the consumption of sugar as a first generation carbon source and emission of the greenhouse gas CO₂. As an illustration, a glucose-based process is co-fed with formic acid, which can be generated by capturing CO₂ from fermentation offgas followed by electrochemical reduction with renewable electricity. This “closed carbon loop” concept is demonstrated by a case study in which cofeeding formic acid is shown to significantly increase the yield of biomass on glucose of the industrially relevant yeast species Yarrowia lipolytica. First, the optimal feed ratio of formic acid to glucose is established using chemostat cultivations. Subsequently, guided by a dynamic fermentation process model, a fed-batch protocol is developed and demonstrated on laboratory scale. Finally, the developed fed-batch process is tested and proven to be scalable at pilot scale. Extensions of the concept are discussed to apply the concept to anaerobic fermentations, and to recycle the O₂ that is co-generated with the formic acid to aerobic fermentation processes for intensification purposes.

Original language	English
Pages (from-to)	2142-2151
Number of pages	10
Journal	Biotechnology and Bioengineering
Volume	119
Issue number	8
DOIs	https://doi.org/10.1002/bit.28115
Publication status	Published - 2022

Keywords

cofeeding
formic acid
greenhouse gas emission reduction
scale up
Yarrowia lipolytica

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/bit.28115

Biotech Bioengineering - 2022 - van Winden - Towards closed carbon loop fermentations Cofeeding of Yarrowia lipolyticaFinal published version, 1.92 MBLicence: CC BY-NC

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title = "Towards closed carbon loop fermentations: Cofeeding of Yarrowia lipolytica with glucose and formic acid",

abstract = "A novel fermentation process was developed in which renewable electricity is indirectly used as an energy source in fermentation, synergistically decreasing both the consumption of sugar as a first generation carbon source and emission of the greenhouse gas CO2. As an illustration, a glucose-based process is co-fed with formic acid, which can be generated by capturing CO2 from fermentation offgas followed by electrochemical reduction with renewable electricity. This “closed carbon loop” concept is demonstrated by a case study in which cofeeding formic acid is shown to significantly increase the yield of biomass on glucose of the industrially relevant yeast species Yarrowia lipolytica. First, the optimal feed ratio of formic acid to glucose is established using chemostat cultivations. Subsequently, guided by a dynamic fermentation process model, a fed-batch protocol is developed and demonstrated on laboratory scale. Finally, the developed fed-batch process is tested and proven to be scalable at pilot scale. Extensions of the concept are discussed to apply the concept to anaerobic fermentations, and to recycle the O2 that is co-generated with the formic acid to aerobic fermentation processes for intensification purposes.",

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AU - Noorman, Henk J.

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AB - A novel fermentation process was developed in which renewable electricity is indirectly used as an energy source in fermentation, synergistically decreasing both the consumption of sugar as a first generation carbon source and emission of the greenhouse gas CO2. As an illustration, a glucose-based process is co-fed with formic acid, which can be generated by capturing CO2 from fermentation offgas followed by electrochemical reduction with renewable electricity. This “closed carbon loop” concept is demonstrated by a case study in which cofeeding formic acid is shown to significantly increase the yield of biomass on glucose of the industrially relevant yeast species Yarrowia lipolytica. First, the optimal feed ratio of formic acid to glucose is established using chemostat cultivations. Subsequently, guided by a dynamic fermentation process model, a fed-batch protocol is developed and demonstrated on laboratory scale. Finally, the developed fed-batch process is tested and proven to be scalable at pilot scale. Extensions of the concept are discussed to apply the concept to anaerobic fermentations, and to recycle the O2 that is co-generated with the formic acid to aerobic fermentation processes for intensification purposes.

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Towards closed carbon loop fermentations: Cofeeding of Yarrowia lipolytica with glucose and formic acid

Abstract

Keywords

UN SDGs

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