<p>Biovalorisation of lignocellulosic biomass is gaining interest in the field of bioprocess technology for the production of high value biochemicals. This study aimed to develop and optimize a process for xylan recovery from EnZolv-pretreated cotton stalk (CSPT), followed by enzymatic production of xylo- and cello-oligosaccharides. First, a conventional alkaline extraction was performed on untreated and EnZolv-pretreated cotton stalk using NaOH (2–12%&#xa0;w/v), at 35–50&#xa0;°C for 8–24&#xa0;h. A maximum experimental xylan recovery of 38.5% was achieved at 12% NaOH, 45&#xa0;°C, and 24&#xa0;h whereas the Box-Behnken design (BBD), predicted 22% recovery at same factor combination. Second, a hydrothermal-assisted alkaline process (12% NaOH, 121&#xa0;°C for 1&#xa0;h) resulted in xylan recoveries of 20.6% and 34.9% from untreated and EnZolv-pretreated CS, respectively. Third, a sequential process was implemented in which untreated and EnZolv-pretreated CS were first subjected to alkaline extraction under optimized NaOH conditions followed by hydrothermal treatment at 121&#xa0;°C for 1&#xa0;h. This two-step strategy increased xylan recovery to 30.9% (untreated CS) and 54.3% (EnZolv-pretreated CS). The recovered xylan and the residual cellulose-rich cotton stalk were subsequently used as substrates for enzymatic hydrolysis, yielding 12.365&#xa0;mg&#xa0;mL <sup>−1</sup> XOS from semi-purified xylan and 1.759&#xa0;mg&#xa0;mL<sup>−1</sup> COS from the cellulose fraction, thereby demonstrating an integrated route for valorizing both hemicellulosic and cellulosic components of cotton stalk.</p>

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Optimized sequential alkaline–hydrothermal xylan recovery from EnZolv-pretreated cotton stalk and enzymatic production of xylo- and cello-oligosaccharides

  • Santhoshkumar Subramaniam,
  • Kumutha Karunanandham,
  • A. S. M. Raja,
  • S. K. Shukla,
  • B. Sanjeev,
  • Sivakumar Uthandi

摘要

Biovalorisation of lignocellulosic biomass is gaining interest in the field of bioprocess technology for the production of high value biochemicals. This study aimed to develop and optimize a process for xylan recovery from EnZolv-pretreated cotton stalk (CSPT), followed by enzymatic production of xylo- and cello-oligosaccharides. First, a conventional alkaline extraction was performed on untreated and EnZolv-pretreated cotton stalk using NaOH (2–12% w/v), at 35–50 °C for 8–24 h. A maximum experimental xylan recovery of 38.5% was achieved at 12% NaOH, 45 °C, and 24 h whereas the Box-Behnken design (BBD), predicted 22% recovery at same factor combination. Second, a hydrothermal-assisted alkaline process (12% NaOH, 121 °C for 1 h) resulted in xylan recoveries of 20.6% and 34.9% from untreated and EnZolv-pretreated CS, respectively. Third, a sequential process was implemented in which untreated and EnZolv-pretreated CS were first subjected to alkaline extraction under optimized NaOH conditions followed by hydrothermal treatment at 121 °C for 1 h. This two-step strategy increased xylan recovery to 30.9% (untreated CS) and 54.3% (EnZolv-pretreated CS). The recovered xylan and the residual cellulose-rich cotton stalk were subsequently used as substrates for enzymatic hydrolysis, yielding 12.365 mg mL −1 XOS from semi-purified xylan and 1.759 mg mL−1 COS from the cellulose fraction, thereby demonstrating an integrated route for valorizing both hemicellulosic and cellulosic components of cotton stalk.