Assessing the Physiological Properties of Baker's Yeast Based on Single-cell Raman Spectrum Technology

Overview

Journal Synth Syst Biotechnol

Specialty Biotechnology

Date 2024 Nov 4

PMID 39493334

Authors

Xi Sun

Xin Zhou

Ran Yu

Xiaofang Zhou

Jun Zhang

Teng Xu

Jianmei Wang

Mengqi Li

Xiaoting Li

Min Zhang

Jian Xu

Jia Zhang

Affiliations

Soon will be listed here.

Abstract

With rapid progress in the yeast fermentation industry, a comprehensive commercial yeast quality assessment approach integrating efficiency, accuracy, sensitivity, and cost-effectiveness is required. In this study, a new yeast quality assessment method based on single-cell Raman technology was developed and contrasted with traditional methods. The findings demonstrated significant associations (Pearson correlation coefficient of 0.933 on average) between the two methods in measuring physiological indicators, including cell viability and intracellular trehalose content, demonstrating the credibility of the Raman method compared to the traditional method. Furthermore, the sensitivity of the Raman method in viable but non-culturable cells was higher in measuring yeast cell viability (17.9 % more sensitive). According to the accurate quantitative analysis of metabolic activity level (MAL) of yeast cells, the cell vitality was accurately quantified at population and single-cell levels, offering a more comprehensive assessment of yeast fermentation performance. Overall, the single-cell Raman method integrates credibility, feasibility, accuracy, and sensitivity in yeast quality assessment, offering a new technological framework for quality assessments of live-cell yeast products.

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