Abstract
Brukina, a traditional fermented beverage smoothie made from milk and millet, is popular in Ghana and other West African countries due to its tasty flavor, high nutritional content, and affordability. Despite its widespread consumption, the nature of its production through artisanal fermentation processes presents concerns regarding microbial consistency, nutritional optimization, and food safety. This literature review explores the potential of metagenomic approaches to uncover microbial diversity, functional capacity, and safety profiles of Brukina. By integrating insights from amplicon-targeted and shotgun whole-genome sequencing studies on fermented foods, we highlight how next-generation sequencing technologies can characterize lactic acid bacteria, yeast, and other microorganisms that drive fermentation. Additionally, we discuss how metagenomics can identify functional genes influencing carbohydrate metabolism, flavor and aroma generation, and production of antimicrobial resistance compounds. Thus, metagenomics provides a powerful framework for assessing public health risks and nutritional benefits. Bioinformatic tools have also been highlighted, and their relevant application in analyzing sequenced data to achieve taxonomic classification, identification of biochemical pathways, and functional profiling of microbial ecology of fermented foods. This review outlines key research gaps and recommends future directions, including starter culture development, standardization of Brukina production, multi-omics integration in metagenomics, and microbiome-informed food safety standards. Metagenomic profiling of Brukina holds promise for improving product quality, consumer safety, and scientific understanding of traditional fermented foods. By tackling the challenges raised, metagenomic techniques can be extremely helpful in maximizing Brukina fermentation, guaranteeing food safety, and maintaining the customs that give this product its distinctive character.