Fabio Herrera‐Rocha scite author profile

Cocoa fermentation plays a crucial role in producing flavor and bioactive compounds of high demand for food and nutraceutical industries. Such fermentations are frequently described as a succession of three main groups of microorganisms (i.e., yeast, lactic acid, and acetic acid bacteria), each producing a relevant metabolite (i.e., ethanol, lactic acid, and acetic acid). Nevertheless, this view of fermentation overlooks two critical observations: the role of minor groups of microorganisms to produce valuable compounds and the influence of environmental factors (other than oxygen availability) on their biosynthesis. Dissecting the metabolome during spontaneous cocoa fermentation is a current challenge for the rational design of controlled fermentations. This study evaluates variations in the metabolic fingerprint during spontaneous fermentation of fine flavor cocoa through a multiplatform metabolomics approach. Our data suggested the presence of two phases of differential metabolic activity that correlate with the observed variations on temperature over fermentations: an exothermic and an isothermic phase. We observed a continuous increase in temperature from day 0 to day 4 of fermentation and a significant variation in flavonoids and peptides between phases. While the second phase, from day four on, was characterized for lower metabolic activity, concomitant with small upward and downward fluctuations in temperature. Our work is the first to reveal two phases of metabolic activity concomitant with two temperature phases during spontaneous cocoa fermentation. Here, we proposed a new paradigm of cocoa fermentation that considers the changes in the global metabolic activity over fermentation, thus changing the current paradigm based only on three main groups of microorganism and their primary metabolic products.

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Dissecting industrial fermentations of fine flavour cocoa through metagenomic analysis

Fernández-Niño

Rodríguez-Cubillos

Herrera‐Rocha

et al. 2021

Sci Rep

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The global demand for fine-flavour cocoa has increased worldwide during the last years. Fine-flavour cocoa offers exceptional quality and unique fruity and floral flavour attributes of high demand by the world's elite chocolatiers. Several studies have highlighted the relevance of cocoa fermentation to produce such attributes. Nevertheless, little is known regarding the microbial interactions and biochemistry that lead to the production of these attributes on farms of industrial relevance, where traditional fermentation methods have been pre-standardized and scaled up. In this study, we have used metagenomic approaches to dissect on-farm industrial fermentations of fine-flavour cocoa. Our results revealed the presence of a shared core of nine dominant microorganisms (i.e. Limosilactobacillus fermentum, Saccharomyces cerevisiae, Pestalotiopsis rhododendri, Acetobacter aceti group, Bacillus subtilis group, Weissella ghanensis group, Lactobacillus_uc, Malassezia restricta and Malassezia globosa) between two farms located at completely different agro-ecological zones. Moreover, a community metabolic model was reconstructed and proposed as a tool to further elucidate the interactions among microorganisms and flavour biochemistry. Our work is the first to reveal a core of microorganisms shared among industrial farms, which is an essential step to process engineering aimed to design starter cultures, reducing fermentation times, and controlling the expression of undesirable phenotypes.

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Omics approaches to understand cocoa processing and chocolate flavor development: A review

Herrera‐Rocha

Fernández-Niño

Cala

et al. 2023

Food Research International

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Lipidomic profiling of bioactive lipids during spontaneous fermentations of fine-flavor cocoa

et al. 2022

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Effects of processing conditions on hydrolysates of proteins from whole whey and formation of Maillard reaction products

García

Herrera‐Rocha

Cavajalino

et al. 2021

J. Food Process. Preserv.

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The increasing nutraceutical market has led to the interest in multidisciplinary research for new insights on the discovery, design, and development of nutraceuticals. In the last decades, enzymatic hydrolysis of food proteins has given added value to food byproducts, such as whey, fish byproducts, collagen, and other food byproducts containing proteins (de Castro & Sato, 2015). Through enzymatic hydrolysis, different health effects have been attributed to derived peptides, including antimicrobial properties, blood pressure lowering effect, cholesterol lowering ability, antithrombotic and antioxidant capacity, enhancement of mineral absorption, immunomodulatory effect, and opioid activities (Jamdar et al., 2010). Among the bioactive peptides resulting from protein hydrolysis, antioxidant peptides play a key role in the market as antioxidant natural products.As a by-product, whey disposal may cause environmental issues; thus, it is necessary to valorize whey to generate value-added products for the food industry (Lappa et al., 2019). Whey can be used

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