One-Step or Two-Step Acid/Alkaline Pretreatments to Improve Enzymatic Hydrolysis and Sugar Recovery from Arundo Donax L.

Tang, Shangyuan; Cao, Yushen; Xu, Chunping; Wu, Yue; Li, Lingci; Ye, Peng; Luo, Ying; Gao, Yifan; Liao, Yong-Hong; Yan, Qiliang; Cheng, Xian

doi:10.3390/en13040948

Cited by 5 publications

(5 citation statements)

References 42 publications

(96 reference statements)

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“…While FeCl 3 effectively dissolves hemicellulose and recovers soluble sugars, it falls short in enhancing enzymatic hydrolysis. Further treatment with NaOH in the second step enhanced delignification, improving the efficiency of enzymatic hydrolysis [29]. Similarly in two-stage pretreatment of Miscanthus using acid and lime, higher recoveries of both glucose (>80%) and xylose (>70%) were observed, outperforming the results of single-stage pretreatments [121].…”

Section: Morphology and Crystallinity Before And After Acidic And Alk...mentioning

confidence: 96%

“…The two-stage acid-alkaline pretreatment exhibited the highest reducing sugar yields, 56.9 g/L glucose and 4.2 g/L xylose, followed by NaOH pretreatment with reducing sugar yields of 51.6 g/L glucose and 13.5 g/L xylose, and finally, H 2 SO 4 pretreatment with yields of 29.2 g/L glucose and 5.1 g/L xylose [26]. In a comparable context of sequential acid-alkaline pretreatments involving H 2 SO 4 , FeCl 3 , NaOH, and a two-stage FeCl 3 -NaOH process for Arundo donax by [29], the combined acid-alkaline treatment outperformed individual acid and alkaline pretreatments. The total soluble sugars obtained from H 2 SO 4 and FeCl 3 pretreatments were in the lower range of 236.2 to 255.9 mg/g of reducing sugar, as opposed to NaOH treatment, which achieved a maximum of 379.7 mg/g of reducing sugar.…”

Section: Morphology and Crystallinity Before And After Acidic And Alk...mentioning

confidence: 99%

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Comparative Analysis of Acidic and Alkaline Pretreatment Techniques for Bioethanol Production from Perennial Grasses

Johannes,

Xuan

2024

Energies

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This review paper examines acid and alkaline pretreatments on perennial grasses for second-generation (2G) bioethanol production, a relatively unexplored area in this field. It compares the efficiency of these pretreatments in producing fermentable sugar and bioethanol yield. This study finds that alkaline pretreatment is more effective than acidic pretreatment in removing lignin and increasing sugar yield, leading to higher ethanol yields. However, it is costlier and requires longer reaction times than acidic pretreatment, while acidic pretreatment often leads to the formation of inhibitory compounds at higher temperatures, which is undesirable. The economic and environmental impacts of lignocellulosic biomass (LCB) are also assessed. It is revealed that LCB has a lower carbon but higher water footprint and significant costs due to pretreatment compared to first-generation biofuels. This review further explores artificial intelligence (AI) and advanced technologies in optimizing bioethanol production and identified the gap in literature regarding their application to pretreatment of perennial grasses. This review concludes that although perennial grasses hold promise for 2G bioethanol, the high costs and environmental challenges associated with LCB necessitate further research. This research should focus on integrating AI to optimize the pretreatment of LCB, thereby improving efficiency and sustainability in 2G biofuel production.

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Section: Morphology and Crystallinity Before And After Acidic And Alk...mentioning

confidence: 96%

Section: Morphology and Crystallinity Before And After Acidic And Alk...mentioning

confidence: 99%

Comparative Analysis of Acidic and Alkaline Pretreatment Techniques for Bioethanol Production from Perennial Grasses

Johannes,

Xuan

2024

Energies

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“…Combined pretreatments seem to increase the efficiency of the process compared to the individual technologies [81,82]; they allow the obtention of high sugar yields with milder operation conditions and require lower solvent and enzyme amounts, thus improving the cost and sustainability of the final product [83][84][85]. However, Galbe and Wallberg [45] have some doubts about the real applicability of combined pretreatments because of their elevated costs and complexity.…”

Section: Combined Pretreatmentsmentioning

confidence: 99%

“…The most basic configuration for a two-step chemical pretreatment is to recover the hemicellulosic fraction through a low pH pretreatment and then apply an alkaline method to the remaining fiber to separate the lignin from the cellulose [81,83,90].…”

Section: Two-step Pretreatmentsmentioning

confidence: 99%

Advanced Bioethanol Production: From Novel Raw Materials to Integrated Biorefineries

et al. 2021

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The production of so-called advanced bioethanol offers several advantages compared to traditional bioethanol production processes in terms of sustainability criteria. This includes, for instance, the use of nonfood crops or residual biomass as raw material and a higher potential for reducing greenhouse gas emissions. The present review focuses on the recent progress related to the production of advanced bioethanol, (i) highlighting current results from using novel biomass sources such as the organic fraction of municipal solid waste and certain industrial residues (e.g., residues from the paper, food, and beverage industries); (ii) describing new developments in pretreatment technologies for the fractionation and conversion of lignocellulosic biomass, such as the bioextrusion process or the use of novel ionic liquids; (iii) listing the use of new enzyme catalysts and microbial strains during saccharification and fermentation processes. Furthermore, the most promising biorefinery approaches that will contribute to the cost-competitiveness of advanced bioethanol production processes are also discussed, focusing on innovative technologies and applications that can contribute to achieve a more sustainable and effective utilization of all biomass fractions. Special attention is given to integrated strategies such as lignocellulose-based biorefineries for the simultaneous production of bioethanol and other high added value bioproducts.

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“…The purpose of pretreatment is to open the structure of a complex matrix such as lignocellulose, thereby reducing the crystallinity of the material and making the cellulose accessible, separating the components of the lignocellulosic biomass, and removing the lignin. 2,3 The advantages of biologically mediated pretreatment using enzymes are high specificity of enzymes for cellulosic substrates, and carrying out the process in aqueous media. In addition, biological pretreatment is more environmen-tally friendly, and does not require the use of toxic and corrosive chemicals.…”

Section: Introductionmentioning

confidence: 99%

LPMO as a Key Enzyme in the Sustainable Conversion of Lignocellulosic Biomass

Rezić¹,

Andlar²,

Presečki

2023

Kemija U Industriji

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The importance of the lytic polysaccharide monooxygenase (LPMO) enzyme in the preparation of lignocellulosic raw materials for production in biorefineries has been confirmed in numerous investigations. Therefore, LPMO enzymes were investigated to explore the enzyme-substrate interaction with the aim of successful biomass conversion in biorefinery processes. After reductive activation of LPMOs active site, they cleave the substrate and prepare it for biomass degradation by hydrolytic enzymes. In this paper, the role of LPMO in lignocellulosic biomass conversion is described based on the recent studies of: LPMO enzyme structure, LPMO substrate preferences, and the LPMO reaction mechanism. These findings are important for the selection of suitable bioprocess conditions with the aim of LPMO activation/stabilisation in biorefinery production processes.

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One-Step or Two-Step Acid/Alkaline Pretreatments to Improve Enzymatic Hydrolysis and Sugar Recovery from Arundo Donax L.

Cited by 5 publications

References 42 publications

Comparative Analysis of Acidic and Alkaline Pretreatment Techniques for Bioethanol Production from Perennial Grasses

Comparative Analysis of Acidic and Alkaline Pretreatment Techniques for Bioethanol Production from Perennial Grasses

Advanced Bioethanol Production: From Novel Raw Materials to Integrated Biorefineries

LPMO as a Key Enzyme in the Sustainable Conversion of Lignocellulosic Biomass

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