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Evaluation of the effects of different chemical pretreatments in sugarcane bagasse on the response of enzymatic hydrolysis in batch systems subject to high mass loads

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  • Paz-Cedeno, Fernando Roberto
  • Henares, Lucas Ragnini
  • Solorzano-Chavez, Eddyn Gabriel
  • Scontri, Mateus
  • Picheli, Flávio Pereira
  • Miranda Roldán, Ismael Ulises
  • Monti, Rubens
  • Conceição de Oliveira, Samuel
  • Masarin, Fernando

Abstract

In the present study, sugarcane bagasse (SB) was subjected to different pretreatments. The pretreated SB was characterized chemically and structurally and was enzymatically hydrolyzed using a commercial enzyme preparation. Pretreatment with sulfite-NaOH was the most efficient for removing lignin while keeping cellulose intact. In addition, sulfite-NaOH pretreatment presented the best response to the enzymatic hydrolysis of cellulose and xylan, reaching conversions of 90%. The increase in consistency (≥10%) in the enzymatic hydrolysis of SB pretreated with sulfite-NaOH showed a loss of cellulose and xylan conversions efficiencies of 28 and 37%, respectively. However, enzymatic hydrolysis with a consistency of 20% resulted in a maximum rate of glucose and xylose formation of 8.5 and 3.0 g L−1 h−1, respectively, and an enzymatic hydrolysate containing 80 and 33 g L−1 of glucose and xylose, respectively. The enzymatic hydrolysis assay in a bioreactor with 20% consistency promoted faster liquefaction of SB, resulting in a higher maximum rate of glucose production (10.6 g L−1 h−1). The increase in the concentration and rate of formation of fermentable sugars in the enzymatic hydrolysate can partially avoid steps of concentration of the hydrolysate, resulting in less energy consumption and greater productivity of the bioproducts obtained from the hydrolysate, such as cellulosic ethanol (2G ethanol).

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  • Paz-Cedeno, Fernando Roberto & Henares, Lucas Ragnini & Solorzano-Chavez, Eddyn Gabriel & Scontri, Mateus & Picheli, Flávio Pereira & Miranda Roldán, Ismael Ulises & Monti, Rubens & Conceição de Olive, 2021. "Evaluation of the effects of different chemical pretreatments in sugarcane bagasse on the response of enzymatic hydrolysis in batch systems subject to high mass loads," Renewable Energy, Elsevier, vol. 165(P1), pages 1-13.
    • Handle: RePEc:eee:renene:v:165:y:2021:i:p1:p:1-13
    DOI: 10.1016/j.renene.2020.10.092
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    1. Moretti, Marcia Maria de Souza & Bocchini-Martins, Daniela Alonso & Nunes, Christiane da Costa Carreira & Villena, Maria Arévalo & Perrone, Olavo Micali & Silva, Roberto da & Boscolo, Maurício & Gomes, 2014. "Pretreatment of sugarcane bagasse with microwaves irradiation and its effects on the structure and on enzymatic hydrolysis," Applied Energy, Elsevier, vol. 122(C), pages 189-195.
    2. Caspeta, Luis & Caro-Bermúdez, Mario A. & Ponce-Noyola, Teresa & Martinez, Alfredo, 2014. "Enzymatic hydrolysis at high-solids loadings for the conversion of agave bagasse to fuel ethanol," Applied Energy, Elsevier, vol. 113(C), pages 277-286.
    3. Ge, Leilei & Wang, Peng & Mou, Haijin, 2011. "Study on saccharification techniques of seaweed wastes for the transformation of ethanol," Renewable Energy, Elsevier, vol. 36(1), pages 84-89.
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    1. Roberto Paz Cedeno, Fernando & Belon de Siqueira, Breno & Gabriel Solorzano Chavez, Eddyn & Ulises Miranda Roldán, Ismael & Moreira Ropelato, Leonardo & Paul Martínez Galán, Julián & Masarin, Fernando, 2022. "Recovery of cellulose and lignin from Eucalyptus by-product and assessment of cellulose enzymatic hydrolysis," Renewable Energy, Elsevier, vol. 193(C), pages 807-820.
    2. Wang, Peng & Su, Yan & Tang, Wei & Huang, Caoxing & Lai, Chenhuan & Ling, Zhe & Yong, Qiang, 2022. "Revealing enzymatic digestibility of kraft pretreated larch based on a comprehensive analysis of substrate-related factors," Renewable Energy, Elsevier, vol. 199(C), pages 1461-1468.
    3. Bai, Zhi-Yuan & You, Shuai & Zhang, Fang & Dong, Zhi-Wei & Zhao, Yi-Fan & Wen, Hong-Jian & Wang, Jun, 2023. "Efficient fermentable sugar production from mulberry branch based on a rational design of GH10 xylanase with improved thermal stability," Renewable Energy, Elsevier, vol. 206(C), pages 566-573.

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