Effect of oxygen mass transfer on the kinetics of Baeyer-Villiger oxidation using a recombinant whole-cell biocatalyst

IF 9 1区环境科学与生态学 Q1 AGRICULTURAL ENGINEERING Bioresource Technology Pub Date : 2025-02-04 DOI:10.1016/j.biortech.2025.132148

Patrik Cabadaj , Viera Illeová , Magdalena Lech , Marek Bučko , Milan Polakovič

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Abstract

Performance of resting cells of Escherichia coli expressing cyclohexanone monooxygenase was investigated in a Baeyer-Villiger (BV) oxidation. The impact of oxygen mass transfer on bicyclic lactone production and oxygen metabolic consumption was examined at varying biocatalyst and bicyclic ketone concentrations. Initial rate measurements were conducted with oxygen mass transfer coefficient (k_La) ranging from 19 h⁻¹ to 83 h⁻¹. Results varied notably depending on the initial bicyclic ketone concentration. Below 4 g/L, BV oxidation followed zero-order kinetics for the ketone and oxygen. Intrinsic specific rates for bicyclic lactone production and metabolic oxygen consumption were 1.4 mmol/g/h and 1.7 mmol/g/h, respectively. Mass transfer limitations intensified with higher biocatalyst concentrations and lower k_La-values. A refined conceptual model of oxygen demand for metabolism and BV oxidation was proposed. Above 4 g/L, substrate inhibition of BV oxidation was evident, while metabolic oxygen consumption was less affected. Bicyclic ketone consumption rates indicated intracellular ketone accumulation.

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氧传质对重组全细胞生物催化剂Baeyer-Villiger氧化动力学的影响。

用Baeyer-Villiger （BV）氧化法研究了表达环己酮单加氧酶的大肠杆菌静息细胞的性能。在不同的生物催化剂和双环酮浓度下，研究了氧传质对双环内酯生产和氧代谢消耗的影响。初始速率测量时，氧传质系数（kLa）范围为19 h-1 ~ 83 h-1。结果因初始双环酮浓度的不同而有显著差异。在4 g/L以下，酮和氧的BV氧化遵循零级动力学。双环内酯产生的内在比速率和代谢耗氧量分别为1.4 mmol/g/h和1.7 mmol/g/h。传质限制随着生物催化剂浓度的升高和kla值的降低而增强。提出了一种改进的代谢和BV氧化需氧量概念模型。在4 g/L以上，底物对BV氧化的抑制作用明显，而对代谢耗氧量的影响较小。双环酮消耗率表明细胞内酮积累。

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来源期刊

Bioresource Technology 工程技术-能源与燃料

CiteScore

20.80

自引率

19.30%

发文量

2013

审稿时长

12 days

期刊介绍： Bioresource Technology publishes original articles, review articles, case studies, and short communications covering the fundamentals, applications, and management of bioresource technology. The journal seeks to advance and disseminate knowledge across various areas related to biomass, biological waste treatment, bioenergy, biotransformations, bioresource systems analysis, and associated conversion or production technologies. Topics include: • Biofuels: liquid and gaseous biofuels production, modeling and economics • Bioprocesses and bioproducts: biocatalysis and fermentations • Biomass and feedstocks utilization: bioconversion of agro-industrial residues • Environmental protection: biological waste treatment • Thermochemical conversion of biomass: combustion, pyrolysis, gasification, catalysis.