Continuous and Semicontinuous Reaction Systems for High-Solids Enzymatic Hydrolysis of Lignocellulosics

Gonzalez‐Quiroga, Arturo; Bula, Antonio; Padilla, Ricardo Vásquez; Costa, Aline Carvalho da; Filho, Rubens Maciel

doi:10.1590/0104-6632.20150324s00003547

Cited by 8 publications

(10 citation statements)

References 36 publications

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“…The two step enzyme saccharification increased the reducing sugar due to high sugar concentration which may block further enzyme hydration. It was previously reported that removal of accumulated sugar prevents feedback inhibition experienced in the initial step (Qi et al 2011;Ouyang et al 2013;Quiroga et al 2015).…”

Section: Two-step Enzymatic Saccharification Of High-pressure Steam Pmentioning

confidence: 97%

Influence of High-Pressure Steam Pretreatment on the Structure of Rice Husk and Enzymatic Saccharification in a Two-Step System

et al. 2017

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This study aimed at developing an operational high-pressure steam pretreatment (HPSP) to effectively modify rice husk for enzymatic saccharification. The HPSP was performed at 160 to 200 °C under 0.3 to 2.8 MPa for 2 to 10 min. The efficiency of this method was based on the chemical composition, scanning electron microscopy (SEM), Fourier transform infrared (FTIR), and X-ray diffraction (XRD) analyses. Optimum pretreatment conditions (200 °C, 1.85 MPa for 7 min), enzyme concentration at 30 FPU/g and temperature at 60 °C for 48 h of continuous saccharification effectively produced sugar (21.1 g/L = 0.422 g/g dry substrate) at a saccharification degree of 53.87%. Conducting a secondstep enzymatic saccharification resulted in additional sugar production (7.9 g/L = 0.158 g/g substrate) and a 20.44% saccharification degree. In contrast, the two-step saccharification process (48 and 24 h) achieved optimal sugar yield of 0.581 g/g substrate and saccharification degree of 73.5%. Additionally, the process improved the yield of monomeric sugars of glucose (0.465 g/g), xylose (0.010 g/g), and cellobiose (0.063 g/g). Therefore, the combination of the high-pressure steam pretreatment with thermostable cellulase from Bacillus licheniformis 2D55 in a two-step enzymatic saccharification process is an economically viable method in rice husk bioprocessing for sugar production.

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Section: Two-step Enzymatic Saccharification Of High-pressure Steam Pmentioning

confidence: 97%

Influence of High-Pressure Steam Pretreatment on the Structure of Rice Husk and Enzymatic Saccharification in a Two-Step System

et al. 2017

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“…The two-step process was based on the optimization of the enzyme adsorption on the biomass during the first short stage of the process (about 1 h) and the successive optimization of extensive hydrolysis during the second, long stage of the process (up to 48 h). A similar strategy was modelled by González Quiroga et al [9]. They proposed a two-step enzymatic hydrolysis at different biomass loadings in different continuous reactors.The further development of the proposed two-step strategies asks for the quantitative characterization of the hydrolysis of cellulose in real biomass.…”

mentioning

confidence: 94%

“…Gusakov et al [7] tested the cellulose conversion in a batch reactor and in a plug-flow reactor to select the best configuration in terms of cellulose conversion. Nowadays, further studies are focused on innovative strategies to combine two fundamental targets: the maximization of both sugar concentration in the hydrolysate and polysaccharides conversion [8,9]. Typically, these two targets are in contrast with one another: high biomass loading (15-20 wt%) favours high soluble sugar concentration and low polysaccharides conversion, and low biomass loading (about 5 wt%) provides low sugar concentration and high polysaccharides conversion.…”

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confidence: 99%

Kinetic Characterization of Enzymatic Hydrolysis of Apple Pomace as Feedstock for a Sugar-Based Biorefinery

et al. 2020

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The enzymatic hydrolysis of cellulose from biomass feedstock in the sugar-based biorefinery chain is penalized by enzyme cost and difficulty to approach the theoretical maximum cellulose conversion degree. As a consequence, the process is currently investigated to identify the best operating conditions with reference to each biomass feedstock. The present work reports an investigation regarding the enzymatic hydrolysis of apple pomace (AP). AP is an agro-food waste largely available in Europe that might be exploited as a sugar source for biorefinery purposes. A biomass pre-treatment step was required before the enzymatic hydrolysis to make available polysaccharides chains to the biocatalyst. The AP samples were pre-treated through alkaline (NaOH), acid (HCl), and enzymatic (laccase) delignification processes to investigate the effect of lignin content and polysaccharides composition on enzymatic hydrolysis. Enzymatic hydrolysis tests were carried out using a commercial cocktail (Cellic®CTec2) of cellulolytic enzymes. The effect of mixing speed and biomass concentration on the experimental overall glucose production rate was assessed. The characterization of the glucose production rate by the assessment of pseudo-homogeneous kinetic models was proposed. Data were analysed to assess kinetic parameters of pseudo-mechanistic models able to describe the glucose production rate during AP enzymatic hydrolysis. In particular, pseudo-homogeneous Michaelis and Menten, as well as Chrastil’s models were used. The effect of lignin content on the enzymatic hydrolysis rate was evaluated. Chrastil’s model provided the best description of the glucose production rate.

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“…There are a number of indications that enzymatic hydrolysis could benefit from a continuous process partly due to the potential to overcome product inhibitions. It is known that the enzymes used for the saccharification of cellulose are inhibited by the presence of glucose and cellobiose, limiting the possible sugar concentration in the hydrolyzed liquid .…”

Section: Introductionmentioning

confidence: 99%

Oscillating flow bioreactors: An enabling technology for sustainable biorefining operations?

Muster-Slawitsch

Buchmaier

Brunner

et al. 2020

J Adv Manuf & Process

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In this work a novel reactor is evaluated on its potential to intensify biobased processing via a novel potentially continuous enzymatic hydrolysis process. An oscillatory flow bioreactor is applied in batch and recirculating mode, the latter mimicking the flow pattern of a continuous process. The recirculating mode operation can intensify cellulose conversion to hydrolyzed sugar liquid significantly, namely with enabling high solid processing and reaching >10% higher cellulose conversion than the respective operation in batch mode. Resulting sugar concentrations reach >90 mg/mL with the potential to enable the elimination of further concentration steps in down-stream processing, having a positive impact on the overall efficiency and sustainability of further processing steps to biofuels or biochemicals. K E Y W O R D S enzymatic hydrolysis, continuous processing, oscillatory flow

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Continuous and Semicontinuous Reaction Systems for High-Solids Enzymatic Hydrolysis of Lignocellulosics

Cited by 8 publications

References 36 publications

Influence of High-Pressure Steam Pretreatment on the Structure of Rice Husk and Enzymatic Saccharification in a Two-Step System

Influence of High-Pressure Steam Pretreatment on the Structure of Rice Husk and Enzymatic Saccharification in a Two-Step System

Kinetic Characterization of Enzymatic Hydrolysis of Apple Pomace as Feedstock for a Sugar-Based Biorefinery

Oscillating flow bioreactors: An enabling technology for sustainable biorefining operations?

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