Lignocellulose conversion for biofuel: a new pretreatment greatly improves downstream biocatalytic hydrolysis of various lignocellulosic materials

Wi, Seung Gon; Cho, Eun Jin; Lee, Dae‐Seok; Lee, Soo Jung; Lee, Young Ju; Bae, Hyeun‐Jong

doi:10.1186/s13068-015-0419-4

Cited by 177 publications

(105 citation statements)

References 42 publications

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“…In this study, the ''one-factor at-a-time'' optimization strategy was applied to augment hydrolytic efficiency by optimizing time, temperature, acid concentration and ratio of solid to acid solution respectively [26,27]. Fig 2 has shown that the maximal glucose concentration (6.37 g/L) was obtained under the hydrolysis condition of 1:7 ratio of solid to acid solution, 32 % (w/v) concentration of sulfuric acid solution at 90℃ for 90 min whose combined optimization effect could contribute to an approximately 142-fold increase in glucose concentration.…”

Section: Optimization Of Acid Hydrolysis Conditionmentioning

confidence: 99%

Isoprenoids Production from Lipid-Extracted Microalgal Biomass Residues Using the Engineered <em>E. coli</em>

Wang¹,

Yang²

2017

Preprint

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Microalgae are recognized as a third generation feedstock for biofuel production due to its rapid growth rate and lignin-free characteristic. In this study, the lipid extracted microalgal biomass residues was used as the material to produce isoprene, α-pinene and β-pinene with the engineered E. coli strain. We adopted an optimal sulfuric acid hydrolysis method (1:7 ratio of solid to acid solution, 32 % (w/v) concentration of sulfuric acid solution at 90℃ for 90 min) to convert holocellulose into glucose efficiently (6.37 g/L) and explored a novel detoxification strategy (phosphoric acid/calcium hydroxide) to remove inhibitors notably. 55.32 % acetic acid, 99.19 % furfural and 98.22 % 5-HMF (5-hydroxymethylfurfural) were cut down with the phosphoric acid/calcium hydroxide method, and the fermentation concentration of isoprene (223.23 mg/L), α-pinene (382.21 μg/L) and β-pinene (17.4 mg/L) using the detoxified hydrolysate as the carbon source account for approximately 86.02 %, 90.16 % and 88.32 % of those produced by the engineered E. coli strain fermented on pure glucose, respectively.

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Section: Optimization Of Acid Hydrolysis Conditionmentioning

confidence: 99%

Isoprenoids Production from Lipid-Extracted Microalgal Biomass Residues Using the Engineered <em>E. coli</em>

Wang¹,

Yang²

2017

Preprint

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“…Based on the above analysis, in this study, we introduced two pretreatment methods to treat peanut hull prior to hydrolysis by cellulase, popping [17] and HPAC [18], with HPAC being an efficient method, including hydrogen peroxide and acetic acid. Meanwhile, to further enhance the isoprene production, we detoxified the enzymatic hydrolysate of peanut hull pretreated by HPAC.…”

Section: Introductionmentioning

confidence: 99%

Isoprene Production on Enzymatic Hydrolysate of Peanut Hull Using Different Pretreatment Methods

Wang

et al. 2016

BioMed Research International

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The present study is about the use of peanut hull for isoprene production. In this study, two pretreatment methods, hydrogen peroxide-acetic acid (HPAC) and popping, were employed prior to enzymatic hydrolysis, which could destroy the lignocellulosic structure and accordingly improve the efficiency of enzymatic hydrolysis. It is proven that the isoprene production on enzymatic hydrolysate with HPAC pretreatment is about 1.9-fold higher than that of popping pretreatment. Moreover, through High Performance Liquid Chromatography (HPLC) analysis, the amount and category of inhibitors such as formic acid, acetic acid, and HMF were assayed and were varied in different enzymatic hydrolysates, which may be the reason leading to a decrease in isoprene production during fermentation. To further increase the isoprene yield, the enzymatic hydrolysate of HPAC was detoxified by activated carbon. As a result, using the detoxified enzymatic hydrolysate as the carbon source, the engineered strain YJM21 could accumulate 297.5 mg/L isoprene, which accounted for about 90% of isoprene production by YJM21 fermented on pure glucose (338.6 mg/L). This work is thought to be the first attempt on isoprene production by E. coli using peanut hull as the feedstock. More importantly, it also shows the prospect of peanut hull to be considered as an alternative feedstock for bio-based chemicals or biofuels production due to its easy access and high polysaccharide content.

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“…A successful pretreatment process for lignocellulosic biomass implies the effective separation of the components and their successive exploitation (Kumar et al 2009;Amendola et al 2012;Wi et al 2015). The selection of a superior pretreatment process strictly depends on the downstream utilization of pretreated lignocellulosic biomass (Beukes and Pletschke 2011).…”

Section: Introductionmentioning

confidence: 99%

In situ Autohydrolysis for the Glucose Production from Sago Pith Waste with DIC Technology

Sarip¹,

Hossain²,

Negm³

et al. 2016

BioResources

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Instant controlled pressure drop (DIC) technology was utilized in the production of glucose from sago pith waste (SPW). In situ autohydrolysis was conducted in a DIC reactor to obtain the maximum glucose production. The influence of pressure, acid concentration, and treatment time on the glucose yield from SPW subjected to DIC-assisted in situ autohydrolysis was determined, and the experimental conditions were optimized using the response surface method. The results showed that the linear term of acid concentration and the quadratic terms of pressure and time had a significant effect on the glucose yield. The optimized experimental conditions for maximum glucose production (48.21%) from SPW subjected to DIC-assisted autohydrolysis were a pressure of 0.1 MPa, acid concentration of 0.1 M, and time of 4 min. The findings demonstrated that DIC technology has the potential to be utilized for the commercial production of glucose from SPW.

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Lignocellulose conversion for biofuel: a new pretreatment greatly improves downstream biocatalytic hydrolysis of various lignocellulosic materials

Cited by 177 publications

References 42 publications

Isoprenoids Production from Lipid-Extracted Microalgal Biomass Residues Using the Engineered <em>E. coli</em>

Isoprenoids Production from Lipid-Extracted Microalgal Biomass Residues Using the Engineered <em>E. coli</em>

Isoprene Production on Enzymatic Hydrolysate of Peanut Hull Using Different Pretreatment Methods

In situ Autohydrolysis for the Glucose Production from Sago Pith Waste with DIC Technology

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