A roadmap for renewable C2–C3 glycols production: a process engineering approach

Marchesan, Andressa Neves; Oncken, Marina Pinho; Filho, Rubens Maciel; Maciel, Maria Regina Wolf

doi:10.1039/c9gc02949d

Cited by 39 publications

(64 citation statements)

References 229 publications

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“…101 In contrast, this technique is non-environmentally friendly and gives a low yield of production. 102 In 2019, the global market size of 1,3-PDO exceeded USD 490 million, which was approximately two-thirds that of conventional PTT production. 103 Thus, an emerging bio-based 1,3-PDO from a renewable source, specifically glycerol, is enticing and profitable.…”

Section: Global Market Of Biochemical Production From Glycerolmentioning

confidence: 99%

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C₃ chemicals: current and future trends

Minh

Samudrala

Bhattacharya

2022

Sustainable Energy Fuels

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Section: Global Market Of Biochemical Production From Glycerolmentioning

confidence: 99%

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C₃ chemicals: current and future trends

Minh

Samudrala

Bhattacharya

2022

Sustainable Energy Fuels

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“…Among the various substrates and products that we evaluated, we identi ed that ethylene glycol (EG) was a highly promising substrate for orthogonal production of a variety of chemicals because it minimized the interactions between biomass and chemical producing pathways. Today, EG is produced primarily by the petrochemical industry from ethylene, however, renewable alternatives are currently in the early stages of development (31,32). In particular, EG can be produced from the electrochemical conversion of CO 2 (11,13), as well as from the chemocatalytic conversion of cellulosic materials and glycerol (a common waste in industrial biofuel and soap production) (31,32).…”

Section: Introductionmentioning

confidence: 99%

“…Today, EG is produced primarily by the petrochemical industry from ethylene, however, renewable alternatives are currently in the early stages of development (31,32). In particular, EG can be produced from the electrochemical conversion of CO 2 (11,13), as well as from the chemocatalytic conversion of cellulosic materials and glycerol (a common waste in industrial biofuel and soap production) (31,32). Thus, though unconventional as a feedstock, EG could serve as a replacement for glucose in the modern bioprocess.…”

Section: Introductionmentioning

confidence: 99%

Engineering Escherichia Coli for the Utilization of Ethylene Glycol

Pandit

Harrison

Mahadevan

2020

Preprint

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Background: A considerable challenge in the development of bioprocesses for producing chemicals and fuels has been the high cost of feedstocks relative to oil prices, making it difficult for these processes to compete with their conventional petrochemical counterparts. Hence, in the absence of high oil prices in the near future, there has been a shift in the industry to produce higher value compounds such as fragrances for cosmetics. Yet, there is still a need to address climate change and develop biotechnological approaches for producing large market, lower value chemicals and fuels.Results: In this work, we study ethylene glycol (EG), a novel feedstock that we believe has promise to address this challenge. We engineer Escherichia coli (E. coli) to consume EG and as a case study for chemical production, examine glycolate production. The best fermentation performance led to the production of 10.4 g/L of glycolate after 112 hours of production time in a fed-batch bioreactor. Our results clearly suggest that oxygen concentration is an important factor in the assimilation and use of EG as a substrate. We also find that the uptake rates for EG are sufficient to satisfy commercial benchmarks for productivity and yield. Finally, our use of metabolic modeling sheds light on the intracellular distribution through central metabolism implicating flux to 2-phosphoglycerate as the primary route for EG assimilation.Conclusion: Overall, our work suggests that EG could provide a renewable starting material for commercial biosynthesis of fuels and chemicals that may achieve economic parity with petrochemical feedstocks while sequestering carbon dioxide.

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“…Among the various substrates and products that we evaluated, we identified that ethylene glycol (EG) was a highly promising substrate for orthogonal production of a variety of chemicals because it minimized the interactions between biomass and chemical producing pathways. Today, EG is produced primarily by the petrochemical industry from ethylene, however, renewable alternatives are currently in the early stages of development [11,12]. In particular, EG can be produced from the electrochemical conversion of CO 2 [13,14], from the chemocatalytic conversion of cellulosic materials and glycerol (a common waste in industrial biofuel and soap production) [11,12], as well as from the depolymerization of poly(ethylene terephthalate) (PET) plastic (an abundant waste material) to its monomers [15][16][17][18].…”

mentioning

confidence: 99%

“…Today, EG is produced primarily by the petrochemical industry from ethylene, however, renewable alternatives are currently in the early stages of development [11,12]. In particular, EG can be produced from the electrochemical conversion of CO 2 [13,14], from the chemocatalytic conversion of cellulosic materials and glycerol (a common waste in industrial biofuel and soap production) [11,12], as well as from the depolymerization of poly(ethylene terephthalate) (PET) plastic (an abundant waste material) to its monomers [15][16][17][18]. Thus, though unconventional as a feedstock, EG could serve as a sustainable and/or renewable replacement for glucose in the modern bioprocess.…”

mentioning

confidence: 99%

Engineering Escherichia coli for the utilization of ethylene glycol

2021

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Background A considerable challenge in the development of bioprocesses for producing chemicals and fuels has been the high cost of feedstocks relative to oil prices, making it difficult for these processes to compete with their conventional petrochemical counterparts. Hence, in the absence of high oil prices in the near future, there has been a shift in the industry to produce higher value compounds such as fragrances for cosmetics. Yet, there is still a need to address climate change and develop biotechnological approaches for producing large market, lower value chemicals and fuels. Results In this work, we study ethylene glycol (EG), a novel feedstock that we believe has promise to address this challenge. We engineer Escherichia coli (E. coli) to consume EG and examine glycolate production as a case study for chemical production. Using a combination of modeling and experimental studies, we identify oxygen concentration as an important metabolic valve in the assimilation and use of EG as a substrate. Two oxygen-based strategies are thus developed and tested in fed-batch bioreactors. Ultimately, the best glycolate production strategy employed a target respiratory quotient leading to the highest observed fermentation performance. With this strategy, a glycolate titer of 10.4 g/L was reached after 112 h of production time in a fed-batch bioreactor. Correspondingly, a yield of 0.8 g/g from EG and productivity of 0.1 g/L h were measured during the production stage. Our modeling and experimental results clearly suggest that oxygen concentration is an important factor in the assimilation and use of EG as a substrate. Finally, our use of metabolic modeling also sheds light on the intracellular distribution through central metabolism, implicating flux to 2-phosphoglycerate as the primary route for EG assimilation. Conclusion Overall, our work suggests that EG could provide a renewable starting material for commercial biosynthesis of fuels and chemicals that may achieve economic parity with petrochemical feedstocks while sequestering carbon dioxide.

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A roadmap for renewable C2–C3 glycols production: a process engineering approach

Abstract: A review of strategies and challenges for chemical and biochemical production and purification of C2–C3 glycols from renewable sources.

Cited by 39 publications

References 229 publications

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C₃ chemicals: current and future trends

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C₃ chemicals: current and future trends

Engineering Escherichia Coli for the Utilization of Ethylene Glycol

Engineering Escherichia coli for the utilization of ethylene glycol

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A roadmap for renewable C2–C3 glycols production: a process engineering approach

Abstract: A review of strategies and challenges for chemical and biochemical production and purification of C2–C3 glycols from renewable sources.

Cited by 39 publications

References 229 publications

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C3 chemicals: current and future trends

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C3 chemicals: current and future trends

Engineering Escherichia Coli for the Utilization of Ethylene Glycol

Engineering Escherichia coli for the utilization of ethylene glycol

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Product

Resources

About

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C₃ chemicals: current and future trends

Valorisation of glycerol through catalytic hydrogenolysis routes for sustainable production of value-added C₃ chemicals: current and future trends