Chocolate production suffered a vast impact with the emergence of the “witches’ broom” disease in cocoa plants. To recover cocoa production, many disease-resistant hybrid plants have been developed. However, some different cocoa hybrids produce cocoa beans that generate chocolate with variable quality. Fermentation of cocoa beans is a microbiological process that can be applied for the production of chocolate flavor precursors, leading to overcoming the problem of variable chocolate quality. The aim of this work was to use a cocktail of microorganisms as a starter culture on the fermentation of the ripe cocoa pods from PH15 cocoa hybrid, and evaluate its influence on the microbial communities present on the fermentative process on the compounds involved during the fermentation, and to perform the chocolate sensorial characterization. According to the results obtained, different volatile compounds were identified in fermented beans and in the chocolate produced. Bitterness was the dominant taste found in non-inoculated chocolate, while chocolate made with inoculated beans showed bitter, sweet, and cocoa tastes. 2,3-Butanediol and 2,3-dimethylpyrazine were considered as volatile compounds making the difference on the flavor of both chocolates. Saccharomyces cerevisiae UFLA CCMA 0200, Lactobacillus plantarum CCMA 0238, and Acetobacter pasteurianus CCMA 0241 are proposed as starter cultures for cocoa fermentation.
Cocoa beans from different geographical and genetic origins show distinct fermentation dynamics which result in different chocolate qualities. In order to understand the effects of genetic improvement of cocoa plants, in this work volatile compounds and proteins profiles of beginning and end of the fermentation from different cocoa hybrids (CEPEC2004, PH15, PS1319, SJ02) were searched. Moreover, sensorial characterization of the produced chocolate from these hybrids was performed. According to the results obtained, different volatile compounds were identified in fermented beans and in the chocolate produced. Chocolate from CEPEC2004 was the most accepted by judges and correlated with sweet and bitter taste which can be explained by the presence of desired flavor compounds, such as 2,3-butanediol and 2-methyl-1-butanol. A higher presence of acids (undesirable compounds) was observed in chocolates samples from PS1319 hybrid, that have resulted in the low acceptance by judges. In addition, MALDI-TOF MS analysis showed that during fermentation the protein profile was different among the hybrids, which indicates this kind of compounds also contributes to the cocoa-specific flavor.
Microbial diversity, final concentration of volatiles compounds during fermentation and the characterization and acceptability of chocolates of three cocoa hybrids (PH 9, PH 15 and PH 16) were evaluated. Hanseniaspora uvarum, Pichia kluyveri, Pichia caribbica and Saccharomyces cerevisiae were the predominant yeasts in the three fermentations. Lactobacillus plantarum, Acetobacter pasteurianus, Bacillus cereus and Lysinibacillus fusiformis were the common bacterial species isolated from the fermentations. The PH 9 hybrid showed highest diversity of lactic acid bacteria and acetic acid bacteria. Twenty‐seven volatile compounds were identified during the cocoa fermentation of all hybrids. Chocolate from PH 9 hybrid had most desirable flavors and obtained the most ideal score in acceptance test. Chocolate from PH 15 hybrid was considered the most bitter, acidic and astringent. Chocolates produced by different cocoa hybrids showed differences in sensory attributes and acceptance. Therefore, special management is required for the different hybrid fermentations to obtain high‐quality chocolate. Practical Applications As a solution to the recovery of the cocoa crop in Brazil, many hybrids resistant to the disease called “witches’ broom” were developed, but the impact of these crosses on cocoa quality, consequently in chocolate is not known. The producers’ cooperatives and farmers of cocoa have no technical or scientific information about the behavior of cocoa hybrids during spontaneous fermentation process, which, oftentimes give rise to an uncontrolled fermentation of cocoa hybrids mixture. The results of this paper could be used among the producers’ cooperatives and cocoa farmers for guidance about the influence of genetic improvement on the quality of cocoa fermented beans and chocolates, particularly among the three hybrids evaluated in this study.
BACKGROUND: Fermented cocoa beans (Theobroma cacao L.) are a pivotal raw material for chocolate production. A cocktail yeast applied in the cocoa fermentation process can promote the formation of pleasant metabolites. Saccharomyces, Pichia and Hanseniaspora have been widely used in fermentation to improve the final product organoleptic profile, highlighting that fermentation is a critical point for chocolate flavour precursor production. This study aims to evaluate the impact of Pichia kluyveri and Saccharomyces cerevisiae strains as starter cultures on the fermentation for two cocoa hybrids, FA13 and CEPEC2002. RESULTS: During fermentation processes, volatile organic compounds (VOCs) and protein profiles were assessed. Chocolates produced were also assessed regarding the presence of VOCs. Eighty VOCs were identified using gas chromatography coupled to mass spectrometry analysis. Mass spectrometry provided the protein profile evolution during fermentation and showed that the profiles changed with inoculation type (spontaneous versus inoculated fermentation). Chocolate obtained from FA13 inoculated with S. cerevisiae strain contained a greater amount of organics acids, being categorised as sourer than chocolate produced by spontaneous fermentation of FA13. CEPEC2002 inoculated with S. cerevisiae strain in co-culture with P. kluyveri strain generated less sour and sweeter chocolate than spontaneous fermentation only.CONCLUSIONS: Chocolates from inoculated assays with starter cultures were more accepted by evaluators, highlighting that P. kluyveri and S. cerevisiae influence the composition of VOCs. Besides, protein profiles also changed throughout fermentation. Further investigation should be conducted to clarify protein degradation dynamics during inoculated fermentations to define which of the microbial cultures positively affect the chocolate sensory characteristics.
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