Temperature, Salinity and Garlic Additive Shape the Microbial Community During Traditional Beetroot Fermentation Process

Overview

Journal Foods

Specialty Biotechnology

Date 2023 Aug 26

PMID 37628078

Authors

Justyna Staninska-Pieta

Jakub Czarny

Lukasz Wolko

Pawel Cyplik

Agnieszka Drozdzynska

Martyna Przybylak

Katarzyna Ratajczak

Agnieszka Piotrowska-Cyplik

Affiliations

Soon will be listed here.

Abstract

Plant-based traditional fermented products are attracting a lot of interest in global markets. An example of them is beetroot leaven, which is valued for its high bioactive compound content. The variety of production recipes and the spontaneous nature of red beet fermentation favor its high diversity. This study aimed to analyze the impact of external factors-temperature, brine salinity, and garlic dose-on the beetroot fermentation and bacterial metapopulation responsible for this process. The research results confirmed the significant influence of the selected and analyzed factors in shaping the leaven physicochemical profile including organic acid profile and betalain content. Analysis of bacterial populations proved the crucial importance of the first 48 h of the fermentation process in establishing a stable metapopulation structure and confirmed that this is a targeted process driven by the effect of the analyzed factors. , , and were observed to be the core microbiome families of the fermented red beet. Regardless of the impact of the tested factors, the leaven maintained the status of a promising source of probiotic bacteria. The results of this research may be helpful in the development of the regional food sector and in improving the quality and safety of traditionally fermented products such as beetroot leaven.

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