Development of a Quinoa-Based Fermentation Medium for Propagation of and in Opaque Beer Production

Overview

Journal Int J Microbiol

Publisher Wiley

Specialty Microbiology

Date 2025 Feb 18

PMID 39963294

Authors

Shepherd Manhokwe

Tatenda Musarurwa

Talknice Z Jombo

Desmond T Mugadza

Amiel Mugari

Joseph Bare

Scelo Mguni

Fidelis Chigondo

Jane Tafadzwa Muchekeza

Affiliations

Soon will be listed here.

Abstract

Product inconsistency of opaque beer has for long been a tenacious problem in the brewing industry since the current process relies on spontaneous lactic acid fermentation. In order to impede this challenge, there is a need to add lactic acid bacteria (LAB) starter cultures in opaque beer brewing to improve its organoleptic qualities. This study sought to develop a quinoa-based fermentation medium for propagation of and as potential starter cultures in opaque beer production. An evaluation of the stability and tolerance of the LAB under various stress conditions was also done. Fermentation wort from opaque beer brewing and different quinoa-based synthetic media with varying nutritional components was prepared for propagation of LAB. Physiochemical analyses which included pH, Brix value and total titratable acidity (TTA) of monocultured and cocultured synthetic media were measured. The measurements were done at 24 h time intervals ranging from 0 to 96 h. Tolerance studies which included the effect of heat shock, cold shock, oxidative stress and osmotic pressure on the survival rate of LAB were conducted to determine the stability of LAB. MRS with monoculture (MRSp) had a notable change in pH from 4.5 to 3.6 after 24 h. The cocultured (M5p + w) synthetic media and cocultured MRS (MRSp + w) also exhibited change in pH from 4.3 to 3.2 and 4.3 to 3.3, respectively, after 72 h. Brix value in all media samples decreased after 24 h except for the uninoculated MRS sample (MRS C). The synthetic and coculture medium (M5p + w) exhibited an increase in TTA (0.79% (m/v) lactic acid) within the first 24 h. Exposure to heat shock had a significance effect ( < 0.05) on the survival rate of and . The in synthetic media recorded a higher survival rate (27 ± 0.03%) upon exposure to heat shock than (7 ± 0.01%). In contrast, in MRS recorded a higher survival rate (67 ± 0.02%) upon exposure to cold shock and oxidative stress (34 ± 0.01%). The starter cultures tested survived upon exposure to the stress conditions, indicating their potential use in opaque beer production.

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