Ultrasound-assisted hydrolysis of food waste using glucoamylase: Statistical optimization and mechanistic analysis with molecular simulations

Q1 Environmental Science

Bioresource Technology Reports Pub Date : 2024-08-15 DOI:10.1016/j.biteb.2024.101932

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Abstract

This paper reports investigations in food waste hydrolysis using ternary approach that combines statistical optimization, ultrasound-assisted enhancement of hydrolysis kinetics, and molecular simulations that provide physical insight into the process. Initial optimization of hydrolysis parameters (Box–Behnken design) resulted in total reducing sugar yield of 263.4 mg/g biomass in 42 h. Sonication of hydrolysis mixture at 35 kHz at 20 % duty cycle yielded 4× reduction in hydrolysis time with 22 % enhancement in TRS yield (320 mg/g biomass). Analysis of GLCM's secondary structure through FTIR spectra deconvolution revealed significant changes induced by sonication. Sonication led to reduction in α-helix, and increase in random coil content. Molecular dynamics simulations unveiled majority of amino acid residues associated with GLCM binding pocket in α-helix and random coil regions. Consequently, sonication widened the binding pockets, facilitating easier transport of substrate and product. This effect translated into faster kinetics of enzymatic food waste hydrolysis.

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使用葡萄糖淀粉酶对食物垃圾进行超声波辅助水解：利用分子模拟进行统计优化和机理分析

本文报告了利用三元方法对食物垃圾水解的研究，该方法结合了统计优化、超声波辅助水解动力学增强和分子模拟，为该过程提供了物理洞察力。对水解混合物进行 35 千赫、20% 占空比的超声波处理可使水解时间缩短 4 倍，TRS 产量提高 22%（320 毫克/克生物质）。通过傅立叶变换红外光谱解卷积分析 GLCM 的二级结构，发现声波处理引起了显著变化。超声处理导致 α 螺旋减少，随机线圈含量增加。分子动力学模拟显示，与 GLCM 结合袋相关的大部分氨基酸残基位于 α 螺旋和随机线圈区域。因此，超声拓宽了结合袋，使底物和产物更容易运输。这种效应加快了酶水解食物垃圾的动力学过程。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Bioresource Technology Reports Environmental Science-Environmental Engineering

CiteScore

7.20

自引率

0.00%

发文量

390

审稿时长

28 days