Metabolite Profiling of Camel Milk and the Fermentation Bacteria Agent TR1 Fermented Two Types of Sour Camel Milk Using LC-MS in Relation to Their Probiotic Potentials

Overview

Journal Heliyon

Specialty Social Sciences

Date 2024 Sep 2

PMID 39220917

Authors

Qingwen Guo

Qigeqi Dong

Weisheng Xu

Heping Zhang

Xiangyu Zhao

Wanxiong He

Yuxing He

Guofen Zhao

Affiliations

Soon will be listed here.

Abstract

Camel milk is a nutrient-rich diet and fermentation affects its nutritional value and probiotic function. In this study, sour camel milk and oat jujube sour camel milk were prepared using fermentation bacteria agent TR1, and the metabolites of camel milk, sour camel milk and oat jujube sour camel milk were detected using a non-targeted metabolomics approach using liquid chromatography-mass spectrometry (LC-MS).The results showed that the partial least squares discriminant analysis (PLS-DA) with 100 % accuracy and good predictive power detected 343 components in positive ion mode and 220 components in negative ion mode. The differential metabolites were mainly organic acids, amino acids, esters, vitamins and other substances contained in camel milk.It showed that there were significant differences in the metabolites of camel milk, sour camel milk and oat jujube sour camel milk. Based on the pathway enrichment analysis of the three dairy products in the KEGG database, 12 metabolic pathways mainly involved in the positive ion mode and 20 metabolic pathways mainly involved in the negative ion mode were identified. The main biochemical metabolic pathways and signal transduction pathways of the differential metabolites of the three dairy products were obtained. This study provides theoretical support for improving the nutritional quality and probiotic function of camel milk and fermented camel milk products and provides a basis for the development of relevant processing technologies and products for camel milk and fermented camel milk.

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