Article ID Journal Published Year Pages File Type
679092 Bioresource Technology 2016 8 Pages PDF
Abstract

•Optimum thermal acid hydrolysis condition of Chaetomorpha linum was established.•Strain Burkholderia cepacia H-2 biotransforming 5-HMF into FDCA was isolated.•5-HMF concentration and pH value deeply influenced FDCA production.•5-HMF biotransformation in the acid algal hydrolysate was performed.•5-HMF detoxification and FDCA production in the algal hydrolysate was feasible.

Thermal acid hydrolysis is often used to deal with lignocellulosic biomasses, but 5-hydroxy-methylfurfural (5-HMF) formed during hydrolysis deeply influences downstream fermentation. 2,5-Furan-dicarboxylic acid (FDCA), which is in the list of future important biomass platform molecules can be obtained using 5-HMF biotransformation. Based on the connection between 5-HMF removal in acid hydrolysate and FDCA production, the optimum thermal acid hydrolysis condition for macroalgae Chaetomorpha linum was established. Potential microbes capable of transforming 5-HMF into FDCA were isolated and characterized under various parameters and inoculated into algal hydrolysate to perform 5-HMF biotransformation. The optimum hydrolysis condition was to apply 0.5 M HCl to treat 3% algal biomass under 121 °C for 15 min. Isolated Burkholderia cepacia H-2 could transform 2000 mg/L 5-HMF at the initial pH of 7 at 28 °C and 1276 mg/L FDCA was received. Strain B. cepacia H-2 was suitable for treating the algal hydrolysate without dilution, receiving 989.5 mg/L FDCA.

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Physical Sciences and Engineering Chemical Engineering Process Chemistry and Technology
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