2022
DOI: 10.3389/fbioe.2022.850370
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Production of Hexanol as the Main Product Through Syngas Fermentation by Clostridium carboxidivorans P7

Abstract: The production of hexanol from syngas by acetogens has gained attention as a replacement for petroleum-derived hexanol, which is widely used in the chemical synthesis and plastic industries. However, acetogenic bacteria generally produce C2 compounds (e.g., acetate and ethanol) as the main products. In this study, the gas fermentation conditions favorable for hexanol production were investigated at different temperatures (30–37°C) and CO gas contents (30–70%) in batch gas fermentation. Hexanol production incre… Show more

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Cited by 16 publications
(5 citation statements)
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“…Strain P21 also produced similar amounts of hexanol from syngas reported in a previous study using strain P7 with temperature variance [45]. However, strain P21 showed slightly lower hexanol production from syngas compared to strain P7 in previous studies, particularly those utilizing extractive syngas fermentation [32,[46][47][48].…”
Section: Clostridium Strainssupporting
confidence: 65%
“…Strain P21 also produced similar amounts of hexanol from syngas reported in a previous study using strain P7 with temperature variance [45]. However, strain P21 showed slightly lower hexanol production from syngas compared to strain P7 in previous studies, particularly those utilizing extractive syngas fermentation [32,[46][47][48].…”
Section: Clostridium Strainssupporting
confidence: 65%
“…21 Accordingly, concentrations of ethanol in the fermentation broth that microorganisms can tolerate (5-6 wt% 23 from syngas fermentation or 5-12 wt % from glucose fermentation) 24 are higher than non-harmful concentrations of isopropanol (4-5 wt% from syngas fermentation), 25 isobutanol (∼1.6 wt% from glucose fermentation) 26 and 1-hexanol (∼0.2 wt% from glucose fermentation). 27 Besides the nature of the fermentation product, pH, substrate type, microbe type, temperature, aeration, nutrients and additives also influence the extent of inhibition. 21 The concurrent alcohol fermentation and recovery (CARAF) may mitigate the endproduct inhibition problem by allowing continuous product removal during fermentation.…”
Section: Major Challenges For Recovery Of Bioalcohols From Fermentationmentioning
confidence: 99%
“…Realistically achievable concentrations of alcohols in the fermentation broth were assumed, as follows: 6.14 wt% ethanol, 23 5.01 wt% isopropanol including small amounts of acetone, 25 1.61 wt% isobutanol 26 and 0.24 wt% hexanol. 27 Nonetheless, it should be noted that the achievable concentrations of alcohols may vary depending on the type of fermentation process, which would significantly affect the performance of the downstream process. For example, higher concentrations of ethanol (about 5-12 wt%) 24 are achievable in fermentation from glucose compared to fermentation from syngas (about 5-6 wt%).…”
Section: Effects Of Fermentation Products On Downstream Processingmentioning
confidence: 99%
“…Hexanol production was enhanced to 2.34 g/L when ethanol was supplemented [192] Ethanol: 1.40-1.50 Butanol: 0.40-0.50 Hexanol: 0.10-0.20 1 Evaluating the effect of oxygen presence in syngas [193] Ethanol: 2.28 Butanol: 0.74 Optimizing medium and reducing costs [194] Table 3. Cont.…”
Section: Co + 3 H2o  C2h5oh + 4 Co2mentioning
confidence: 99%