Synthesis and application of a novel selective detoxification agent to enhance cellulosic ethanol production

Lichun Shen; Pengxin Liu; Jinju Hou; Shudong Zhang; Juan Wang; Ping Chen; Jing Liang; Qiuzhuo Zhang

doi:10.1016/j.jclepro.2026.147907

Synthesis and application of a novel selective detoxification agent to enhance cellulosic ethanol production

Lichun Shen
, Pengxin Liu
, Jinju Hou
, Shudong Zhang
, Juan Wang
, Ping Chen
, Jing Liang^*
, Qiuzhuo Zhang^*

^*此作品的通讯作者

生态与环境科学学院

East China Normal University
Shanghai Institute of Technology
Shanghai Academy of Landscape Architecture Science and Planning
Ministry of Natural Resources of the People's Republic of China
Institute of Eco-Chongming (IEC)

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Environmental pollution and energy crises have accelerated the development of rice straw-based cellulosic ethanol. However, ferulic acid (FA) which predominantly acts as a fermentation inhibitor produced by alkaline pretreatment processes of rice straw feedstock may substantially compromise bioethanol production efficiency. In this study, a novel molecularly imprinted adsorbent (AEPA₂₅₀@MIPs) was synthesized using enzymatic hydrolysis residue as a matrix to selectively separate FA. Density Functional Theory (DFT) identified 2-MEA as the optimal functional monomer. AEPA₂₅₀@MIPs exhibited excellent selective adsorption performance, with a distribution coefficient (K_d) exceeding 2.67 in competitive adsorption experiments, representing a significant improvement compared to conventional adsorbents. In simulated fermentation systems, AEPA₂₅₀@MIPs achieves a 16.6% enhancement in ethanol production yield. Microporous diffusion, hydrogen bonding, and π-π interactions were identified as key mechanisms for selective adsorption. Compared to previous studies, AEPA₂₅₀@MIPs achieved higher selectivity and reduced glucose loss. This work provides a promising solution to enhance alkaline hydrolysate detoxification and improves the efficiency of bioethanol production.

源语言	英语
文章编号	147907
期刊	Journal of Cleaner Production
卷	551
DOI	https://doi.org/10.1016/j.jclepro.2026.147907
出版状态	已出版 - 18 3月 2026

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可持续发展目标 7 经济适用的清洁能源
可持续发展目标 12 负责任消费和生产

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title = "Synthesis and application of a novel selective detoxification agent to enhance cellulosic ethanol production",

abstract = "Environmental pollution and energy crises have accelerated the development of rice straw-based cellulosic ethanol. However, ferulic acid (FA) which predominantly acts as a fermentation inhibitor produced by alkaline pretreatment processes of rice straw feedstock may substantially compromise bioethanol production efficiency. In this study, a novel molecularly imprinted adsorbent (AEPA250@MIPs) was synthesized using enzymatic hydrolysis residue as a matrix to selectively separate FA. Density Functional Theory (DFT) identified 2-MEA as the optimal functional monomer. AEPA250@MIPs exhibited excellent selective adsorption performance, with a distribution coefficient (Kd) exceeding 2.67 in competitive adsorption experiments, representing a significant improvement compared to conventional adsorbents. In simulated fermentation systems, AEPA250@MIPs achieves a 16.6\% enhancement in ethanol production yield. Microporous diffusion, hydrogen bonding, and π-π interactions were identified as key mechanisms for selective adsorption. Compared to previous studies, AEPA250@MIPs achieved higher selectivity and reduced glucose loss. This work provides a promising solution to enhance alkaline hydrolysate detoxification and improves the efficiency of bioethanol production.",

keywords = "Alkali pretreatment hydrolysate, Cellulosic ethanol, Detoxification, Molecular imprinting, Selective adsorption, Waste valorization",

author = "Lichun Shen and Pengxin Liu and Jinju Hou and Shudong Zhang and Juan Wang and Ping Chen and Jing Liang and Qiuzhuo Zhang",

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AU - Shen, Lichun

AU - Liu, Pengxin

AU - Hou, Jinju

AU - Zhang, Shudong

AU - Wang, Juan

AU - Chen, Ping

AU - Liang, Jing

AU - Zhang, Qiuzhuo

PY - 2026/3/18

Y1 - 2026/3/18

N2 - Environmental pollution and energy crises have accelerated the development of rice straw-based cellulosic ethanol. However, ferulic acid (FA) which predominantly acts as a fermentation inhibitor produced by alkaline pretreatment processes of rice straw feedstock may substantially compromise bioethanol production efficiency. In this study, a novel molecularly imprinted adsorbent (AEPA250@MIPs) was synthesized using enzymatic hydrolysis residue as a matrix to selectively separate FA. Density Functional Theory (DFT) identified 2-MEA as the optimal functional monomer. AEPA250@MIPs exhibited excellent selective adsorption performance, with a distribution coefficient (Kd) exceeding 2.67 in competitive adsorption experiments, representing a significant improvement compared to conventional adsorbents. In simulated fermentation systems, AEPA250@MIPs achieves a 16.6% enhancement in ethanol production yield. Microporous diffusion, hydrogen bonding, and π-π interactions were identified as key mechanisms for selective adsorption. Compared to previous studies, AEPA250@MIPs achieved higher selectivity and reduced glucose loss. This work provides a promising solution to enhance alkaline hydrolysate detoxification and improves the efficiency of bioethanol production.

AB - Environmental pollution and energy crises have accelerated the development of rice straw-based cellulosic ethanol. However, ferulic acid (FA) which predominantly acts as a fermentation inhibitor produced by alkaline pretreatment processes of rice straw feedstock may substantially compromise bioethanol production efficiency. In this study, a novel molecularly imprinted adsorbent (AEPA250@MIPs) was synthesized using enzymatic hydrolysis residue as a matrix to selectively separate FA. Density Functional Theory (DFT) identified 2-MEA as the optimal functional monomer. AEPA250@MIPs exhibited excellent selective adsorption performance, with a distribution coefficient (Kd) exceeding 2.67 in competitive adsorption experiments, representing a significant improvement compared to conventional adsorbents. In simulated fermentation systems, AEPA250@MIPs achieves a 16.6% enhancement in ethanol production yield. Microporous diffusion, hydrogen bonding, and π-π interactions were identified as key mechanisms for selective adsorption. Compared to previous studies, AEPA250@MIPs achieved higher selectivity and reduced glucose loss. This work provides a promising solution to enhance alkaline hydrolysate detoxification and improves the efficiency of bioethanol production.

KW - Alkali pretreatment hydrolysate

KW - Cellulosic ethanol

KW - Detoxification

KW - Molecular imprinting

KW - Selective adsorption

KW - Waste valorization

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DO - 10.1016/j.jclepro.2026.147907

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VL - 551

JO - Journal of Cleaner Production

JF - Journal of Cleaner Production

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ER -

Synthesis and application of a novel selective detoxification agent to enhance cellulosic ethanol production

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