Comparison of methods for detoxification of spruce hydrolysate for bacterial cellulose production

Guo, Xiang; Cavka, Adnan; Jönsson, Leif J.; Hong, Feng

doi:10.1186/1475-2859-12-93

Cited by 99 publications

(64 citation statements)

References 39 publications

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“…Several procedures have been described for the removal of inhibitory compounds from LB hydrolyzates in order to limit their negative action on the fermentation [34]. Among these, the extraction with ethyl acetate [35], ion exchange [36], AC adsorption [37] or biological treatments with microorganisms and enzymes [38] can be referred. The treatment with AC is considered an effective method for the removal of phenolic compounds from LB hydrolyzates because of the large surface area of the charcoal particles, high adsorption capacity, and availability [36].…”

Section: Saccharification Of Cs and Detoxification With Activated Chamentioning

confidence: 99%

“…Among these, the extraction with ethyl acetate [35], ion exchange [36], AC adsorption [37] or biological treatments with microorganisms and enzymes [38] can be referred. The treatment with AC is considered an effective method for the removal of phenolic compounds from LB hydrolyzates because of the large surface area of the charcoal particles, high adsorption capacity, and availability [36]. In addition, because some of these potential inhibitory molecules possess strong antioxidant power, their subsequent desorption from charcoal enables the recovery of bioactive compounds that can be further utilized for value-added applications [18,28,30,33,39].…”

Section: Saccharification Of Cs and Detoxification With Activated Chamentioning

confidence: 99%

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Development of an Energy Biorefinery Model for Chestnut (Castanea sativa Mill.) Shells

et al. 2017

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Chestnut shells (CS) are an agronomic waste generated from the peeling process of the chestnut fruit, which contain 2.7-5.2% (w/w) phenolic compounds and approximately 36% (w/w) polysaccharides. In contrast with current shell waste burning practices, this study proposes a CS biorefinery that integrates biomass pretreatment, recovery of bioactive molecules, and bioconversion of the lignocellulosic hydrolyzate, while optimizing materials reuse. The CS delignification and saccharification produced a crude hydrolyzate with 12.9 g/L of glucose and xylose, and 682 mg/L of gallic acid equivalents. The detoxification of the crude CS hydrolyzate with 5% (w/v) activated charcoal (AC) and repeated adsorption, desorption and AC reuse enabled 70.3% (w/w) of phenolic compounds recovery, whilst simultaneously retaining the soluble sugars in the detoxified hydrolyzate. The phenols radical scavenging activity (RSA) of the first AC eluate reached 51.8 ± 1.6%, which is significantly higher than that of the crude CS hydrolyzate (21.0 ± 1.1%). The fermentation of the detoxified hydrolyzate by C. butyricum produced 10.7 ± 0.2 mM butyrate and 63.9 mL H 2 /g of CS.Based on the obtained results, the CS biorefinery integrating two energy products (H 2 and calorific power from spent CS), two bioproducts (phenolic compounds and butyrate) and one material reuse (AC reuse) constitutes a valuable upgrading approach for this yet unexploited waste biomass.

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Section: Saccharification Of Cs and Detoxification With Activated Chamentioning

confidence: 99%

Section: Saccharification Of Cs and Detoxification With Activated Chamentioning

confidence: 99%

Development of an Energy Biorefinery Model for Chestnut (Castanea sativa Mill.) Shells

et al. 2017

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“…As will be seen further in Section 3.6, detoxification with BC or AC seems to be adequate working with yeasts or bacteria because of the high removals of LS, phenolics and acetic acid. This research gave better results in case of furfurals and weak acids in comparison with Guo et al [17] and Lee et al [22] who removed 94%-96% of furfurals, 14%-28% of acetic acid or 88% of total phenolics.…”

Section: Adsorption With Activated Carbon and Black Carbonmentioning

confidence: 51%

“…The experimental results obtained in this paper together with the fermentation requirements of a specific microorganism permit to establish the detoxification possibilities that might be implemented in different case studies. It should be noted that the study cases represented in Figure 5b belong to hydrolyzates similar to the industrial liquors used in this work such as hardwood hydrolyzates [22,46], softwood hydrolyzates [9,17] and spent sulfite liquors [19,23,35,47]. Main SSL inhibitors can be classified into weak acids, furan derivatives and phenolics among others [48,49].…”

Section: Best Solutions For the Most Common Fermenting Scenariosmentioning

confidence: 99%

“…In recent years, many publications have studied a single detoxification technique coupled with a specific fermentation scenario [2,9,16,19,23,35]. Other papers have studied the combination of detoxification techniques experimentally [10,17,18,20,21,36,37] or from a theoretical viewpoint [26,31,38,39]. Nonetheless, the present research is the first paper working with spent sulfite liquor which compares different detoxification techniques showing which one of them would be adequate to produce seven different fermentation and value-added products (ethanol, bacterial cellulose, xylitol, polyhydroxyalkanoate (PHA), acetone-butanol-ethanol (ABE), succinic acid and polyhydroxybutyrate (PHB).…”

Section: Introductionmentioning

confidence: 99%

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Detoxification of a Lignocellulosic Waste from a Pulp Mill to Enhance Its Fermentation Prospects

2017

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Detoxification is required for sugar bioconversion and hydrolyzate valorization within the biorefining concept for biofuel or bio-product production. In this work, the spent sulfite liquor, which is the main residue provided from a pulp mill, has been detoxified. Evaporation, overliming, ionic exchange resins, and adsorption with activated carbon or black carbon were considered to separate the sugars from the inhibitors in the lignocellulosic residue. Effectiveness in terms of total and individual inhibitor removals, sugar losses and sugar-to-inhibitor removal ratio was determined. The best results were found using the cation exchange Dowex 50WX2 resin in series with the anion exchange Amberlite IRA-96 resin, which resulted in sugar losses of 24.2% with inhibitor removal of 71.3% of lignosulfonates, 84.8% of phenolics, 82.2% acetic acid, and 100% of furfurals. Apart from exchange resins, the results of evaporation, overliming, adsorption with activated carbon and adsorption with black carbon led to total inhibitor removals of 8.6%, 44.9%, 33.6% and 47.6%, respectively. Finally, some fermentation scenarios were proposed in order to evaluate the most suitable technique or combination of techniques that should be implemented in every case.

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Biotechnological Production of Fuel Hydrogen and Its Market Deployment

Lázaro

Sağır

Hallenbeck

2020

Green Energy to Sustainability

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Comparison of methods for detoxification of spruce hydrolysate for bacterial cellulose production

Cited by 99 publications

References 39 publications

Development of an Energy Biorefinery Model for Chestnut (Castanea sativa Mill.) Shells

Development of an Energy Biorefinery Model for Chestnut (Castanea sativa Mill.) Shells

Detoxification of a Lignocellulosic Waste from a Pulp Mill to Enhance Its Fermentation Prospects

Biotechnological Production of Fuel Hydrogen and Its Market Deployment

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