Growth-associated and Non-growth-associated Bioethanol Production Kinetics from Nanoadsorbent-Detoxified Pretreated Hydrolysate

IF 2.3 4区化学 Q3 CHEMISTRY, PHYSICAL

Catalysis Letters Pub Date : 2025-01-21 DOI:10.1007/s10562-024-04868-8

Adeniyi P. Adebule, Isaac A. Sanusi, Gueguim E. B. Kana

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Abstract

Lignocellulosic-based (LCB) bioethanol production is challenged by the presence of inhibitory compounds in pretreated LCB hydrolysates limiting productivity. The negative impact of these inhibitory compounds on LCB bioethanol production kinetics remain understudied. Hence, this study modelled the kinetics of bioethanol fermentation using nanoadsorbent-detoxified potato peel waste (PPW) hydrolysate. Four different fermentation processes under both separate hydrolysis and fermentation (SHF) and simultaneous saccharification and fermentation (SSF) conditions, including A (SHF with non-detoxified hydrolysate), B (SSF with non-detoxified hydrolysate), C (SHF with detoxified hydrolysate), and D (SSF with detoxified hydrolysate) were evaluated for bioethanol productivity. Higher productivity of 1.23 and 1.16-fold increments were recorded for fermentation processes C and D. Thereafter, the experimental data for cell growth, bioethanol production and substrate utilisation were well-fitted by the logistic function, modified Gompertz, and Luedeking-Piret models respectively. Moreover, the obtained root-mean-square error (RMSE) and mean square error (MSE) were low, while the accuracy factor (AF), bias factor (BF), slope and regression coefficient (R²) were close to 1. The bioethanol production processes were largely growth-associated (α) as α values (g ethanol/g substrate) were higher than β values (g ethanol/g substrate/h). The models were effectively implemented, demonstrating their usefulness to elucidate bioethanol productivity kinetics for improved process design and the development of large-scale bioethanol production.

Graphical Abstract

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纳米吸附剂解毒预处理水解液的生长相关和非生长相关生物乙醇生产动力学

基于木质纤维素（LCB）的生物乙醇生产受到预处理的LCB水解物中存在抑制化合物的挑战，限制了生产效率。这些抑制化合物对LCB生物乙醇生产动力学的负面影响仍未得到充分研究。因此，本研究模拟了利用纳米吸附剂解毒马铃薯皮废物（PPW）水解物发酵生物乙醇的动力学。在单独水解和发酵（SHF）和同时糖化和发酵（SSF）条件下，评估了四种不同的发酵工艺，包括A（含非解毒水解液的SHF）、B（含非解毒水解液的SSF）、C（含解毒水解液的SHF）和D（含解毒水解液的SSF）的生物乙醇产量。发酵过程C和d的产量分别增加了1.23倍和1.16倍。随后，细胞生长、生物乙醇产量和底物利用率的实验数据分别通过logistic函数、改进的Gompertz和Luedeking-Piret模型得到了很好的拟合。得到的均方根误差（RMSE）和均方误差（MSE）较低，精度因子（AF）、偏倚因子（BF）、斜率和回归系数（R2）均接近1。由于α值（g乙醇/g底物）高于β值（g乙醇/g底物/h），生物乙醇生产过程主要与生长相关（α）。这些模型有效地实现了，证明了它们对阐明生物乙醇产率动力学的有用性，有助于改进工艺设计和大规模生物乙醇生产的发展。图形抽象

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来源期刊

Catalysis Letters 化学-物理化学

CiteScore

5.70

自引率

3.60%

发文量

327

审稿时长

1 months

期刊介绍： Catalysis Letters aim is the rapid publication of outstanding and high-impact original research articles in catalysis. The scope of the journal covers a broad range of topics in all fields of both applied and theoretical catalysis, including heterogeneous, homogeneous and biocatalysis. The high-quality original research articles published in Catalysis Letters are subject to rigorous peer review. Accepted papers are published online first and subsequently in print issues. All contributions must include a graphical abstract. Manuscripts should be written in English and the responsibility lies with the authors to ensure that they are grammatically and linguistically correct. Authors for whom English is not the working language are encouraged to consider using a professional language-editing service before submitting their manuscripts.