Effects of Tropical Fruit Blends on Fermentative and Pigmentation Aspects of Probiotic Native Cultured Goat Milk

Overview

Journal PeerJ

Date 2025 Jan 17

PMID 39822982

Authors

Isadora Kaline Camelo Pires de Oliveira Galdino

Gabriel Monteiro da Silva

Miqueas Oliveira Morais da Silva

Giordanni Cabral Dantas

Elainy Virginia Dos Santos Pereira

Tiago Almeida de Oliveira

Karina Maria Olbrich Dos Santos

Antonio Silvio do Egito

Flavia Carolina Alonso Buriti

Haissa Roberta Cardarelli

Affiliations

Soon will be listed here.

Abstract

Background: Fruits are sources of bioactive compounds such as phenolics that bring health benefits to consumers. The addition of fruit products and microorganisms with probiotic potential in fermented goat milk can facilitate the acquisition of these benefits through diet. In this sense, the objective of this study was to evaluate the effect of incorporating a mixture of ingredients from jaboticaba (), jambolana (), and mandacaru () fruits on fermentation parameters (pH, titratable acidity, viability of the native culture CNPC003 and the starter culture), associated with pigmentation (phenolic compound content and color) through experimental mixture design.

Methods: A simplex-centroid experimental design was conducted, comprised of seven trials totaling the addition of 30% of the fruit preparations in the final formulation of fermented milk and one control trial (without addition of preparations), with the response being the total phenolic content and the instrumental color parameter a*. Fermentations were carried out with the addition of the native culture CNPC003 and the starter culture Subsequently, analyses of pH, titratable acidity, viability of the native and starter cultures, total phenolic compound content, and the instrumental color parameter a* were performed.

Results: The final pH among trials ranged from 4.55 to 4.69, titratable acidity ranged from 0.59 to 0.64, the population CNPC003 reached levels exceeding 8 log CFU/g, as did the population of . The content of phenolic compounds was higher in trials T1, T5, and T7, as well as the color parameter (a*). The use of experimental mixture design contributed to the development of products with high viability of , high content of phenolic compounds, and a characteristic color of the added fruits, bringing benefits to consumer health.

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