上游微波强化技术发展的基础——以大肠杆菌为例

Q3 Pharmacology, Toxicology and Pharmaceutics
D. Kuznetsov, A. Mironov, V. Neschislyaev, I. Volkhin, A. М. Korolyuk, E. V. Orlova, A. D. Shilina
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引用次数: 0

摘要

介绍。大肠杆菌菌株是用于生产许多重要生物制药产品的主要微生物。地球上没有天然的微波辐射源,因为它被上层大气吸收。没有人怀疑研究微波辐射的生物效应的重要性。致力于这一问题的出版物数量每年都在增长,在药物生产技术中使用微波的新想法也不断出现。揭示微波辐照的主要作用,开发微波强化大肠杆菌培养生长的技术。材料和方法。本研究展示了原子力显微镜、折射法、核磁共振弛豫法、浊度法和光度法的结果,证明了微波强化培养过程的可能性。结果和讨论。研究发现,微波辐照导致质子的迁移率和水分子在生物聚合物和细胞上的吸附发生变化。这些是“非热”微波作用机理的主要环节。一次微波辐照,取决于若干参数,可以减少或增加生物量的生长。对具有luxo操纵子的大肠杆菌菌株的生物发光研究表明,最佳加工条件对细胞荧光素酶的产生和代谢活性没有负面影响。结论。微波辐射强化是一种很有前途的方法,可以为生物技术的各种应用提供新的思路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Basics of the Development of Microwave Intensification of Upstream on the Example of Escherichia coli
Introduction. E. coli strains are the main microorganisms used for the production of a number of important biopharmaceutical products. There are no natural sources of microwave radiation on Earth, as it is absorbed by the upper atmosphere. No one doubts the importance of studying the biological effect of microwave radiation. The number of publications devoted to this problem is growing every year, and new ideas for the use of microwaves in drug production technology are emerging.Aim. Reveal the main effects of microwave irradiation and develop a technology for microwave intensification of E. coli culture growth.Materials and methods. This study presents the results of atomic force microscopy, refractometry, NMR relaxometry, turbidimetry, and lumimetry, demonstrating the possibility of microwave intensification of the cultivation process.Results and discussion. It was found that microwave irradiation leads to changes in the mobility of protons and the adsorption of water molecules on biopolymers and cells. These are the main links in the mechanism of "non-thermal" microwave action. A single microwave irradiation, depending on a number of parameters, can decrease or increase the growth of biomass. Studies of the bioluminescence of the E. coli strain with the lux-operon have shown that the optimal processing conditions do not negatively affect the luciferase production and metabolic activity of cells. Conclusion. The intensification procedure using microwave radiation can be considered a promising method and can provide new ideas for various applications in biotechnology.
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来源期刊
Drug Development and Registration
Drug Development and Registration Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science
CiteScore
1.20
自引率
0.00%
发文量
61
审稿时长
8 weeks
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