将拉曼光谱和一维卷积神经网络建模作为体外转氨酶催化合成药物相关胺前体的实时监测工具。

IF 2.5 3区 生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Julie Østerby Madsen, Sebastian Olivier Nymann Topalian, Mikkel Fog Jacobsen, Tommy Skovby, Krist V. Gernaey, Allan S. Myerson, John Woodley
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引用次数: 0

摘要

拉曼光谱被用于测量烟碱乙酰胆碱受体正异位调节剂在ω-反式胺酶催化转化过程中的药学相关模型胺中间体的浓度。研究人员开发了一个基于一维卷积神经网络的模型,将原始数据增强拉曼光谱直接转化为底物浓度,从而确定ω-反转氨酶将酮转化为胺的过程。该模型显示出非常好的预测能力,建模中光谱的 R2 值高于 0.99,独立数据集的 R2 值为 0.964。不过,该模型无法推断出模型指定浓度之外的浓度。这项工作表明拉曼光谱具有作为生物催化反应实时监测工具的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Raman spectroscopy and one-dimensional convolutional neural network modeling as a real-time monitoring tool for in vitro transaminase-catalyzed synthesis of a pharmaceutically relevant amine precursor

Raman spectroscopy and one-dimensional convolutional neural network modeling as a real-time monitoring tool for in vitro transaminase-catalyzed synthesis of a pharmaceutically relevant amine precursor

Raman spectroscopy has been used to measure the concentration of a pharmaceutically relevant model amine intermediate for positive allosteric modulators of nicotinic acetylcholine receptor in a ω-transaminase-catalyzed conversion. A model based on a one-dimensional convolutional neural network was developed to translate raw data augmented Raman spectra directly into substrate concentrations, with which the conversion from ketone to amine by ω-transaminase could be determined over time. The model showed very good predictive capabilities, with R2 values higher than 0.99 for the spectra included in the modeling and 0.964 for an independent dataset. However, the model could not extrapolate outside the concentrations specified by the model. The presented work shows the potential of Raman spectroscopy as a real-time monitoring tool for biocatalytic reactions.

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来源期刊
Biotechnology Progress
Biotechnology Progress 工程技术-生物工程与应用微生物
CiteScore
6.50
自引率
3.40%
发文量
83
审稿时长
4 months
期刊介绍: Biotechnology Progress , an official, bimonthly publication of the American Institute of Chemical Engineers and its technological community, the Society for Biological Engineering, features peer-reviewed research articles, reviews, and descriptions of emerging techniques for the development and design of new processes, products, and devices for the biotechnology, biopharmaceutical and bioprocess industries. Widespread interest includes application of biological and engineering principles in fields such as applied cellular physiology and metabolic engineering, biocatalysis and bioreactor design, bioseparations and downstream processing, cell culture and tissue engineering, biosensors and process control, bioinformatics and systems biology, biomaterials and artificial organs, stem cell biology and genetics, and plant biology and food science. Manuscripts concerning the design of related processes, products, or devices are also encouraged. Four types of manuscripts are printed in the Journal: Research Papers, Topical or Review Papers, Letters to the Editor, and R & D Notes.
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