Skip to the main content

Original scientific paper

https://doi.org/10.17113/ftb.62.03.24.8350

Biotransformacija nusproizvoda prerade tropskog voća za razvoj analoga kombuche s antioksidacijskim potencijalom

Gabriel Barbosa Câmara orcid id orcid.org/0000-0003-4964-0837 ; Federal University of Ceará, Campus do Pici, Ac. Público, 856 - Pici, 60020-181 Fortaleza-CE, Brazil
Giovana Matias do Prado orcid id orcid.org/0000-0002-3008-7632 ; Federal University of Ceará, Campus do Pici, Ac. Público, 856 - Pici, 60020-181 Fortaleza-CE, Brazil
Paulo Henrique Machado de Sousa orcid id orcid.org/0000-0001-7005-6227 ; Federal University of Ceará, Campus do Pici, Ac. Público, 856 - Pici, 60020-181 Fortaleza-CE, Brazil
Vanessa Bordin Viera orcid id orcid.org/0000-0003-4979-4510 ; Federal University of Campina Grande, Sítio Olho D'água da Bica - Zona Rural, 58175-000, Cuité-PB, Brazil
Helvia Waleska Casullo de Araújo orcid id orcid.org/0000-0003-0337-5986 ; State University of Paraiba, R. Baraúnas, 351 - Universitário, 58429-500, Campina Grande-PB, Brazil
Amélia Ruth Nascimento Lima orcid id orcid.org/0000-0002-3565-5125 ; Federal University of Ceará, Campus do Pici, Ac. Público, 856 - Pici, 60020-181 Fortaleza-CE, Brazil
Antonio Augusto Lima Araujo Filho ; Federal University of Ceará, Campus do Pici, Ac. Público, 856 - Pici, 60020-181 Fortaleza-CE, Brazil
Ícaro Gusmão Pinto Vieira orcid id orcid.org/0000-0002-0576-3643 ; PADETEC – Technological Development Park, Federal University of Ceara, Campus do Pici - Pici, 60440-690, Fortaleza - CE, Brazil
Victor Borges Fernandes orcid id orcid.org/0000-0003-4666-1026 ; PADETEC – Technological Development Park, Federal University of Ceara, Campus do Pici - Pici, 60440-690, Fortaleza - CE, Brazil
Liandra De Souza Oliveira orcid id orcid.org/0000-0002-9925-3723 ; University Center Faculty of Medical Sciences in Campina Grande, R. Manoel Cardoso Palhano, 124-152 - Itararé, 58408-326, Campina Grande-PB, Brazil
Larissa Morais Ribeiro da Silva ; Federal University of Ceará, Campus do Pici, Ac. Público, 856 - Pici, 60020-181 Fortaleza-CE, Brazil


Full text: english pdf 614 Kb

page 361-372

downloads: 4

cite

Download JATS file

Supplements: FTB-62-361-S1.pdf


Abstract

Pozadina istraživanja. U zemlji u kojoj treba zadovoljiti prehrambene potrebe milijuna ljudi, inovativni načini proizvodnje hrane od često zanemarenih agroindustrijskih nusproizvoda mogu predstavljati važnu alternativu u proizvodnji fermentiranih napitaka. U skladu s time, svrha je ovog istraživanja bila procijeniti potencijal nusproizvoda prerade acerole, guave i tamarinda za proizvodnju fermentiranih napitaka.
Eksperimentalni pristup. Tijekom prve (0, 48, 72, 96 i 168 h) i druge fermentacije (0 i 24 h) ispitani su fizikalno-kemijski i mikrobiološki parametri, ukupna antioksidacijska sposobnost i kinetika fermentacije. Kromatografijom je određen kiselinski sastav fermentiranih napitaka, dok je senzorski profil utvrđen testom prihvatljivosti proizvoda.
Rezultati i zaključci. Fizikalno-kemijski parametri svih uzoraka bili su u skladu s važećim zakonodavstvom te su zadovoljavali mikrobiološku kakvoću. Ispitivanjem kinetike fermentacije utvrđeno je smanjenje pH-vrijednosti i udjela topljivih tvari – s prosječnim konačnim pH-vrijednostima od 3,12 za napitak od acerole; 2,85 za napitak od guave i 2,78 za napitak od tamarinda – dok je kiselost uzoraka porasla na konačne vrijednosti od 0,94; 0,75 i 1 %. Od svih uzoraka, napitak od tamarinda je imao najveći udjel topljivih tvari (8,17 g/100 g), dok je onaj od acerole imao najveći antioksidacijski potencijal, izražen u ekvivalentima troloksa ((20,0±0,8) μM/g). Organske kiseline pronađene su u svim uzorcima kombuche, pri čemu je najviše bilo glukuronske kiseline. Svi su uzorci imali zadovoljavajuću senzorsku prihvatljivost, iako je napitak od guave dobio najbolje ocjene. Zaključeno je da se nusproizvodi prerade voća mogu koristiti kao sirovina u proizvodnji alternativnih napitaka kombucha.
Novina i znanstveni doprinos. Budući da su potrošači sve više izbirljivi u pogledu odabira hrane, razvoj proizvoda velike hranjive vrijednosti bitno se povećao u posljednjih nekoliko godina. Novi tipovi fermentiranih napitaka poput kombuche – dobiveni od nusproizvoda prerade tropskog voća radi poboljšanja kemijskog sastava, senzorskih svojstava i hranjive vrijednosti napitaka – pružaju nove mogućnosti konzumacije napitaka te nude veću zdravstvenu korist od tradicionalne kombuche proizvedene samo od kineskog čajevca (Camellia sinensis). Promocija ovih nusproizvoda i napitaka proizvedenih od njih nudi izvrsnu priliku za održivost i komercijalizaciju.

Keywords

nusproizvodi prerade voća; fermentirani napici; funkcionalna hrana; inovativna proizvodnja hrane

Hrčak ID:

321935

URI

https://hrcak.srce.hr/321935

Publication date:

31.10.2024.

Article data in other languages: english

Visits: 20 *




INTRODUCTION

The large amount of by-products generated by agro-industrial processing is one of the challenges of the 21st century (1). Worldwide, 1.3 billion tonnes of by-products are generated annually, including processed by-products and waste from the production chain. According to FAO (2), most of these come from fruit and vegetables, which account for up to 50 % of production, mainly in the processing and postharvest stages (3).

Brazil is a country that produces a wide range of agro-industrial by-products. Due to poor management, this practice can have serious environmental impacts. Acerola, guava and tamarind are perishable products that are sensitive to exogenous factors. During production, high rates of postharvest losses occur, generating a large amount of by-products and non-recyclable waste. It is estimated that waste after harvest and production of juices are very high, reaching losses of 10 to 50 % (4).

The search for viable and economical use of agro-industrial by-products is necessary if the food industry wants to be more sustainable. It also has an impact on the reduction of raw material waste and production costs (5). Many food formulations have been investigated that aim to use artisanal or industrial by-products, leading to an expansion of the plant-based food production.

Fruit by-products can have a high nutritional content, often higher than that of their edible parts. Furthermore, these by-products may also contain bioactive compounds with a higher antioxidant capacity than the pulp (6). In addition, agro-industrial by-products contain many fermentable sugars and nutrients from which microorganisms can produce various substances of industrial importance that can be used for the development of various products, such as kombucha (7).

Kombucha is a slightly sweet and acidic drink generally produced by fermenting black or green tea (Camellia sinensis) using sugar and a cellulose biofilm containing a symbiotic culture of bacteria and yeasts known as SCOBY (8).

The literature has already described the use of other products for the production of kombucha. Examples include herbal infusions, wax mallow flowers, coffee, oak leaves, eucalyptus, bay leaves, fruit juices, milk and soya products, which have proven to be good alternatives to black or green tea (9,10).

In addition, depending on the raw material used to produce kombucha, the final product can have improved chemical composition, sensory and biological properties, which open up new possibilities for beverage production and potentially offers products with more health benefits for the consumers (10).

With this in mind, the study presented here aims to develop kombucha analogues using the agro-industrial by-products of fruit pulp processing. In addition to offering a new product for the consumers, the preparation of the beverage is associated with the use of fruit by-products and the reduction of their environmental impact, minimising their improper disposal. Formulations were made using by-products that were preselected based on their antioxidant activity, and their fermentation kinetics, physicochemical and sensory properties, and organic acid profile were investigated.

MATERIALS AND METHODS

Raw material

By-products of six tropical fruits - acerola (Malpighia emarginata), guava (Psidium guajava), tamarind (Tamarindus indica), passion fruit (Passiflora edulis), mombin (Spondias mombin) and pineapple (Ananas comosus) – were used as raw materials (supplied by Nossa Fruta, a fruit pulp company in Eusébio, Brazil) for the production of fermented beverages, together with sugar (União®, São Paulo, Brazil) and potable water (Naturagua®, Fortaleza, Brazil). The samples were registered in the National System for the Management of Genetic Heritage and Associated Traditional Knowledge (SISGEN) under accession number AA72205 through the Federal University of Ceará, Fortaleza, Brazil.

For the fermentation process, both the symbiotic culture of bacteria and yeasts (SCOBY) and the liquid from the end of the kombucha fermentation test (prepared beforehand) were used as starter culture (provided by our research group, Fortaleza, Brazil). After fermentation, the fruit pulp (supplied by a fruit pulp Nossa Fruta), which corresponds to the by-product of each formulation, was used in the flavouring stage.

Selection of by-products

In order to select the by-products with the best properties for the production of fermented beverages, antioxidant activity was first investigated using the 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid) radical scavenging (ABTS˙+; Sigma-Aldrich, Merck, MO, USA) method as described by Re et al. (11) and adapted by Rufino et al. (12). Different concentrations of the by-products were used and the beverage properties depended on each fruit. An aliquot of 30 μL of each dilution (selected according to the calibration curve) reacted with 3 mL of the ABTS˙+ solution in the dark. The absorbance values of the reaction mixture were measured after 6 min in a spectrophotometer (Kasvi, São José dos Pinhais, Brazil) at 734 nm. A standard curve between 100 and 1500 μM of Trolox (6-hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid; Sigma-Aldrich, Merck) was used as a reference. The measured antioxidant capacity of the samples was expressed as Trolox equivalents (μM/g). Based on these results, three by-products were selected to develop the formulations.

Kombucha formulations

The preparation of all formulations (Fig. S1) started with the infusion phase (at (90±2) °C for 5 min) using drinking water (1000 mL), the specific fruit by-products (10 % m/V) and 10 % sugar. After the infusion phase, the samples were filtered in felt tissue to remove solid residues. Then the resulting liquid was cooled to (24±2) °C and φ(kombucha)=15 % and 20 % (m/V) SCOBY were added, starting fermentation process 1 (F1) in the presence of oxygen. The SCOBY used for all formulations was from the same initial fermentation, and the same amount of this culture was used for all formulations.

As each tested fruit by-product could have a different fermentation kinetics, the fermentation time of each formulation was determined as a function of the pH (model 3505; Jenway, Chelmsford, UK) that was established for all formulations (2.9±1.0) according to the Brazilian Normative Instruction No. 41 (13), which determines a minimum and maximum pH of 2.5 and 4.2 (14,15) for kombucha, respectively.

The second fermentation (F2) was carried out to impart gas and flavour to the beverage, adding 20 % (m/V) of pulp to each formulation. The fermented beverages were then transferred to PET bottles and stored at room temperature (25 °C) for 24 h. Each formulation was prepared in triplicates to ensure a more reliable result. Once the flavouring phase was completed, the formulations were refrigerated at (12±2) °C to slow down the fermentation process. A total of three formulations were prepared after the selection of the by-products: acerola by-product (FBA), guava by-product (FBG) and tamarind by-product (FBT).

Fermentation kinetics

The fermentation kinetics of the formulations was evaluated by pH, titratable acidity and total soluble solids content during the first (F1) and the second (F2) fermentation, the latter also known as flavouring fermentation. During F1, kinetics was measured at 0, 48, 72, 96 and 168 h and during F2 at 0 and 24 h.

The soluble solid content was measured by direct reading of the samples, where an aliquot of each sample was added to the prism (14). These direct readings were done with a portable refractometer (ASKO, São Leopoldo, Brazil), model RT 32.

The pH was determined with potentiometric method using a digital pH metre (model 3505; Jenway) calibrated with pH buffer solutions of 4.0 and 7.0, following the procedure described by Adolfo Lutz Institute (14).

Titratable acidity (TA) was determined by the titrimetric method using 0.1 M NaOH. The results were expressed as percentage of acetic acid (14).

Microbiological analyses

Total coliforms, thermotolerant coliforms, Escherichia coli and aerobic mesophilic bacteria were counted fusing the rapid analysis method known as Compact Dry (Nissui Pharmaceutical CO, Taito-ku, Tokyo), certified by the AOAC International (15). Salmonella sp. was analysed according to the Bacteriological Analytical Manual (16) to evaluate the safety of the developed product. The samples were subjected to pre-enrichment (lactose broth; Kasvi), followed by selective enrichment (tetrathionate broth and Rappaport-Vassiliadis broth; Kasvi) and plating media for Salmonella (xylose lysine deoxycholate agar, Hektoen agar and bismuth sulphite agar; Kasvi).

Determination of organic acids

All samples were injected into HPLC chromatograph LC 10AvP (Shimadzu, Tokyo, Japan) to determine the organic acid content. Before injection, they were filtered through polyvinylidene difluoride (PVDF) filters of 0.45 and 0.22 μm. All mobile phases passed through a 0.22 μm cellulose acetate filter.

A 214 nm UV–Vis detector (SPD-M10AVP; Shimadzu) and LiChrospher® 100 RP-18 column (4.6 mm×250 mm; 5 μm) were used to determine the organic acid content. The 0.2 M KH2PO4 (pH=2.4) was used as the mobile phase and the flow rate was 0.8 mL/min (17). The profiles of glucuronic, lactic, acetic, citric and ascorbic acid were determined based on standard curves previously determined for each substance (Table S1). For all analyses, the column oven remained at 40 °C (CTO-10 AS VP; Shimadzu) and the injection loop was 20 μL. For each organic acid, the limit of detection (LOD), i.e. the lowest concentration of the analyte that can be detected, and the limit of quantification (LOQ), i.e. the lowest concentration of the analyte that can be measured, were determined.

Sensory analysis

The study was submitted to the Ethics Committee (Animal Use Ethics Committee of the Federal University of Ceará, Brazil) and approved with the number 4.729.905. Sensory properties of the selected and optimised formulations were evaluated using an adapted method due to the pandemic caused by COVID-19 and the requirement for social isolation. Sensory analysis was performed on 23 September 2021. Thus, for this study, the check-all-that-apply (CATA), rate-all-that-apply (RATA) and acceptance tests were carried out at the tasters' homes. The preventive measures according to the Brazilian National Health Surveillance Agency (18) were followed in the production and delivery of the formulations, such as the use of gloves and masks.

The acerola, guava and tamarind by-products were delivered to each taster's home in PET bottles containing approx. 100 mL of product, along with a letter containing instructions and the link and QR code to access the form. The tasters were asked to drink mineral water at room temperature between samples to cleanse the palate (14).

The tests were conducted with a group of 60 untrained panellists who were healthy, non-smokers and selected based on their consumption of fermented products and acerola juice, as well as their previous experience with sensory tests. The group consisted of 36 women and 24 men aged between 18 and 65, with more than 85 % of them being younger than 50.

The samples were evaluated in 100-mL plastic cups. Acceptance test forms were available with scores ranging from 1 (I disliked it a lot) to 9 (I liked it a lot) to check the participants’ level of acceptance of appearance, aroma, taste and overall acceptability (19,20). In the CATA test (21), tasters had to select among 20 descriptive terms related to appearance, taste and aroma those that best represented the type of the tested product (listed inTable 1). In the RATA test, the tasters had to rate the applicability of the terms to the samples on a five-point scale, with one being very little and five being very much. The terms used in the RATA test were appearance, aroma and flavour, and the attributes used for each term corresponded to the characteristics present in each formulation.

Table 1 Multiple comparisons of check-all-that-apply (CATA) and rate-all-that-apply (RATA) test results for each attribute in all samples using the McNemar (Bonferroni) procedure and Cochran’s Q test to compare each attribute in kombucha formulations fermented with fruit by-products
CATARATA
AttributeFBAFBGFBTp-valueFBAFBTFBGp-value
Bright(0.7±0.4)a(0.7±0.4)a(0.7±0.5)a0.5(1.9±1.3)a(1.7±1.3)a(1.9±1.3)a0.6
Translucent (clear)(0.6±0.4)a(0.6±0.4)a(0.6±0.4)a0.7(1.7±1.5) a(1.4±1.3)a(1.6±1.5)a0.6
Homogeneous(0.8±0.3)a(0.8±0.4)a(0.7±0.4)a0.6(2.3±1.3)a(2.1±1.4)a(2.4±1.5)a0.6
Sedimented(0.7±0.4)a(0.6±0.4)a(0.7±0.4)a0.5(1.8±1.4)a(2.0±1.6)a(1.7±1.5)a0.5
Presence of bubbles(0.8±0.3)a(0.8±0.4)a(0.8±0.4)a0.5(2.3±1.4)a(2.2±1.6)a(2.5±1.7)a0.4
Sweet scent(0.7±0.4)a(0.8±0.3)a(0.7±0.4)a0.0(1.4±1.1)b(1.6±1.2)b(2.6±1.3)a<0.0001
Citrus scent(0.8±0.3)a(0.8±0.3)a(0.8±0.3)a0.8(2.6±1.5)a(2.2±1.4)a(2.1±1.4)a0.1
Acid flavour(0.7±0.4)a(0.7±0.4)a(0.8±0.4)a0.5(2.2±1.6)a(2.2±1.5)a(1.7±1.4)a0.1
Vinegar scent(0.6±0.4)a(0.6±0.4)a(0.7±0.4)a0.1(1.6±1.4)a(1.9±1.5)a(1.4±1.3)a0.1
Fermented flavour(0.7±0.4)a(0.7±0.4)a(0.7±0.4)a0.8(1.9±1.4)a(1.9±1.4)a(1.6±1.3)a0.2
Acid taste(0.8±0.3)a(0.9±0.3)a(0.8±0.3)a0.0(2.8±1.7)a(2.8±1.4)a(2.5±1.4)a0.6
Sweet taste(0.7±0.4)a(0.7±0.4)a(0.7±0.4)a0.6(1.6±1.2)b(1.6±1.3)b(2.1±1.4)a0.0
Salty taste(0.5±0.4)a(0.5±0.4)a(0.6±0.4)a0.5(1.0±1.2)a(1.0±1.0)a(0.9±1.0)a0.9
Bitter taste(0.6±0.4)a(0.6±0.4)a(0.6±0.4)a0.1(1.4±1.5)a(1.5±1.5)a(1.2±1.3)a0.5
Citrus flavour(0.9±0.2)a(0.8±0.3)a(0.8±0.3)a0.0(3.1±1.3)a(2.5±1.3)b(2.4±1.3)b0.0
Vinegar flavour(0.7±0.4)b(0.6±0.4)a(0.7±0.4)ab0.0(1.8±1.5)a(1.6±1.4)a(1.5±1.5)a0.6
Fermented flavour(0.8±0.4)a(0.7±0.4)a(0.7±0.4)a0.6(2.1±1.5)a(1.9±1.4)a(1.8±1.4)a0.4
Astringent sensation(0.5±0.4)a(0.5±0.5)a(0.5±0.5)a0.2(1.5±1.6)a(1.4±1.5)a(1.3±1.4)a0.7
Spicy sensation(0.5±0.5)a(0.5±0.5)a(0.5±0.5)a0.7(0.9±1.0)a(1.0±1.2)a(1.1±1.3)a0.6
Frizzling sensation(0.7±0.4)a(0.7±0.4)a(0.7±0.4)a0.4(1.6±1.4)a(1.7±1.3)a(1.7±1.3)a0.9

Mean values with the same letters in the same row do not differ at the 5 % significance level for the CATA and RATA analyses, separately. FBA, FBG and FBT=formulation with acerola, guava and tamarind by-product, respectively

Purchase intention was also evaluated using a structured five-point scale, with five representing ’I would certainly buy it’ and one representing ’I would certainly not buy it’ (20).

Statistical analysis

Statistical analysis was performed using analysis of variance (ANOVA) and Tukey’s test (p=0.05), evaluating significant differences between samples subjected to the same analysis. The results of fermentation kinetics were evaluated by regression analysis using Systat software v. 13.2 (22). The data obtained from the sensory analysis were first analysed in terms of variance (ANOVA) and then the mean values of the hedonic values were subjected to the Tukey’s test at 5 % probability. The Cochran Q test was used to compare the frequency means of each CATA attribute. The results were also analysed by principal component analysis (PCA) and presented in two-dimensional graphs. Penalty analysis was performed on the data obtained by CATA to determine whether a present attribute caused a lower or higher preference or did not affect the preference of the samples (23). The results were analysed to assess which attributes should be present (’must have’) or absent (’must not have’) (24). All tests were performed with the Assistat software v. 7.7 beta (25) except for the sensory programme, which was performed with the XLSTAT software v. 4.5 (26).

RESULTS AND DISCUSSION

Antioxidant activity of fruit by-products

Based on the antioxidant activity values obtained, expressed as Trolox equivalent antioxidant capacity (TEAC), three fruit by-products were selected to be used for the development of the fermented beverages: acerola (44.6±0.4), tamarind (28.3±0.3) and guava (2.06±0.05) μmol/g. The guava by-product replaced the mombin by-product (3rd place, (5.70±0.02) μmol/g) as raw material due to the off-season of the mombin fruit. Passion fruit and pineapple had lower values of antioxidant activity ((1.30±0.03) and (1.20±0.01) μmol/g, respectively. Therefore, they were not selected for the preparation of beverages.

The evaluation and consumption of compounds with antioxidant capacity have attracted the interest of researchers and consumers as they are associated with the reduction of degenerative diseases caused by free radicals. Antioxidant capacity is attributed to the ability of the sample to quench free radicals by donating either hydrogen atoms or electrons. Therefore, they can prevent the harmful effects of oxidation and provide several health benefits when included in the human diet (27,28). These benefits are associated with the presence of ascorbic acid, anthocyanins, carotenoids, phenolic compounds and other antioxidants that are easily found in various fruits and vegetables (29).

Silva et al. (6) evaluated bioactive compounds from tropical fruit residues and found high amounts of total phenolic compounds in acerola, guava and mango residues. The content of phenolic compounds could be related to the antioxidant activity of the by-product, although the results obtained in this study are consistent with those reported by the authors.

pH, titratable acidity and total soluble solids during kombucha fermentation

The pH is an important parameter in fermentation processes, as it reduces the growth of pathogenic microorganisms (pH<4.5) and prevents structural changes in antioxidant compounds (30).

During the first fermentation (Fig. 1a), a decrease in pH over time was observed. The initial pH of the acerola by-product was 3.02; after 48 h it decreased to 2, and at the end of F1 it changed to 2.64. Similar results were observed for the guava by-product, where the initial pH was 3.45 and the final pH was 2.85. The pH of tamarind by-product decreased from 3.21 to 2.78 at the end of F1.

Fig. 1 The effect of fermentation time of formulations with acerola, guava or tamarind by-products (FBA, FBG and FBT, respectively) on the average of: a) and b) pH during fermentation 1 and 2, c) and d) titratable acidity (TA) as acetic acid during fermentation 1 and 2, and e) and f) total soluble solids (TSS) during fermentation 1 and 2, respectively
FTB-62-361-f1

After F1, the pH was measured during the flavouring stage (Fig. 1b), which lasted 24 h, and values were measured at 0 and 24 h, when a slight decrease in pH was observed in all formulations. It can be seen that F1 was responsible for a more significant decrease in pH.

In a previous study, the pH of kombucha fermented with rice and barley decreased from the sixth to the eighth day of fermentation (31), which is in alignment with the results of the present study. Similar results were found by Leonarski et al. (30), who prepared kombucha beverages using an acerola by-product. The initial pH of beverages prepared with 1, 3 and 5 % acerola by-product was 3.24, 3.34 and 3.27, respectively, with all samples showing similar behaviour, including a decrease in pH until the 12th day of cultivation. After 15 days of fermentation, a pH of 2.49, 2.54 and 2.58, respectively, was observed, which is very close to the values at the end of F2 in the present study (pH=2.82, 3.12 and 2.78 for FBA, FBG and FBT, respectively;Fig. 1b).

This decrease observed in all formulations can be attributed to the production of organic acids during fermentation, which causes the reduction of the pH of kombucha, reducing the number of possible pathogens and generating a safe drink for consumption, despite being of microbial origin (32). According to Rodrigues et al. (33), a final pH of 2.5 signals the end of the fermentation process, which is close to that observed at the end of F1 in our study (Fig. 1c andFig. 1d).

Fig. 1c andFig 1d show a gradual increase in acidity in all formulations during fermentations 1 and 2. The FBA started with an acidity of 0.32 %, evolving to 0.94 % at the end of F2. On the other hand, FBG had an initial acidity of 0.26 % and a final acidity of 0.75 %. The FBT was the formulation with the highest initial and final acidity (0.44 and 1 %, respectively). Finally, the FBG was the formulation that had the lowest acidity.

Hibiscus-based kombucha (33) had 0.18 % titratable acidity, which is lower than the values found in the present study. This can be explained by the difference in fermentation time and the composition of SCOBY. Tanticharakunsiri et al. (34) prepared kombucha with oolong tea fermented for seven days and found a titratable acidity of approx. 0.6 %, close to what was found at certain times for some formulations in the present study, such as the FBA, with value of 0.6 % at 48 and 72 h (Fig. 1c).

A significant increase in titratable acidity during the fermentation process is expected due to the production of characteristic acids formed as a result of the metabolism of acetic acid bacteria. However, the oscillations observed in this experiment may be due to the rapid volatilization of acetic acid that may have occurred during sample collection or even during the fermentation period due to the portage of the tissue used for nozzle coverage, which may have facilitated the volatilization of acids. A total titratable acidity content between 0.40 and 0.45 % was reported as indicative of the completion of the fermentation process (35).

The production of acids during the fermentation process justifies the variation of total soluble solids since the acetic acid bacteria present in SCOBY consume sugars, converting them into organic acids (36).

At the start of F1, FBA had a total solid content of 6.97 mg/100 g, and at the end 6.63 mg/100 g (Fig. 1e), while at the start of F2, it had significantly higher total solid content (7.50 mg/100 g), which was reduced to 7.13 mg/100 g after 24 h. At the start of F1, FBG had the total solid content of 7.43 mg/100 g and at the end it had 7.30 mg/100 g. It increased at the beginning of F2 (8.10 mg/100 g) and was reduced after 24 h (7.87 mg/100 g). The same observations were perceived for FBT, at the beginning of F1 it had a total solid content of 7.70 mg/100 g and at the end 7.37 mg/100 g, which increased at the start of F2 (8.30 mg/100 g) and reduced to 8.17 mg/100 g at the end of F2 (Fig. 1f).

The soluble solid content was reduced in all formulations during both fermentations (F1 and F2). Their increase at the start of F2 (flavouring stage) can be attributed to the addition of fruit pulp during this stage.

Filho et al. (37) developed fermented drinks with kombucha and kefir and found a reduction in the total soluble solid content with fermentation time, a result similar to that obtained in the present study.

Antioxidant activity and the microbiological safety of kombucha beverages

It is possible to notice reduction in values associated with both dilutions used for beverage preparation and the temperature applied during production. Moreover, a significant difference between one formulation and another may be related not only to the fact that different fruit co-products were used, but also to the climatic conditions and soil composition from which the fruits were harvested (38).

The kombuchas fermented with green tea (39) had an antioxidant activity expressed as Trolox equivalents of 11.35 to 11.50 μmol/g, which is lower than the ones found in the present study for FBT ((20.0±0.8) μmol/g, while kombuchas fermented with black tea (40) had an antioxidant activity ranging from (0.4±0.1) to (9.6±0.3) μmol/g. Antioxidant activity demonstrated in kombucha formulations is of great economic and nutritional importance, as they are beverages made from fruit by-products that still have considerable antioxidant activity.

The developed formulations are safe for consumption from the microbiological point of view, with no Salmonella detected in 25 mL and counts of total and thermotolerant coliforms, E. coli and aerobic mesophiles lower than 1 CFU/mL.

Içen et al. (41) evaluated the antimicrobial potential of kombucha against Gram positive and Gram negative bacteria and found that it has antimicrobial properties towards a wide variety of pathogens (Salmonella sp., L. monocytogenes, Staphylococcus spp., C. albicans, among others), which is confirmed by the absence of Salmonella and E. coli in tested samples in this study.

Furthermore, the use of good manufacturing practices can explain the excellent microbiological quality of the formulations, in addition to the physicochemical and microbial characteristics associated with the fermentation process, such as the pH and presumably high counts of acetic acid bacteria and yeasts, which inhibit the growth of undesirable microorganisms (42).

Organic acids present in kombucha formulations

The three main functional acids associated with kombucha are gluconic acid, d-saccharic acid-1,4-lactone (DSL) and glucuronic acid (43). Glucuronic acid is one of the most important acids in the organism. It is formed in kombucha as a result of glucose oxidation by microorganisms, and is recognised as one of the natural substances with the highest detoxifying potential. It can bind to toxins, increasing their water-solubility and, consequently, making them easier to eliminate by urine (44). Bacteria such as Acetobacter, Gluconobacter and Komagataeibacter spp. (45) use sugar and ethanol (46) to produce gluconic acid, therefore, its presence in tested formulations is possibly linked to the growth of these bacteria.

Glucuronic acid was the main organic acid detected in kombucha samples (Table 2), ranging from 8.0 (FBG) to 14.6 mg/100 mL (FBA). The second organic acid with the highest presence was the acetic acid, which ranged from 5.0 (FBT) to 14.67 mg/100 mL (FBA). Other research (37) involving the analysis of acids in kombucha also identified and quantified the presence of glucuronic acid in the formulations, reinforcing that it is an acid generally present in kombuchas, even with changes in fermentative substrates.

Table 2 Organic acid quantification in formulations of kombucha fermented with fruit by-products, and limits of detection and quantification of HPLC measurement for standard substances used
γ(organic acid)/(mg/mL)
FormulationGlucuronicAscorbicLacticAceticCitric
FBA(14.6±0.2)a(3.28±0.05)a(3.16±0.02)a(14.67±0.08)a(0.00±0.00)b
FBG(8.0±0.2)c(0.14±0.00)b(0.00±0.00)b(7.27±0.06)b(2.60±0.05)a
FBT(11.7±0.4)b(0.00±0.00)c(0.00±0.00)b(5.0±0.2)c(0.00±0.00)b
LOD/(mg/mL)0.0010.0010.010.010.000001
LOQ/(mg/mL)0.0050.0010.030.050.000005

FBA, FBG and FBT=formulation with acerola, guava and tamarind by-product, respectively. The mean value±standard deviation (N=3) followed by equal letters in the same column do not differ from each other according to Tukey’s test (p>0.05). LOD=limit of detection, LOQ=limit of quantification

The formulations that had a lower pH at the end of F2 were FBT and FBA with pH=2.78 and 2.82, respectively (Fig. 1b). We know that a lower pH is related to a higher production of organic acids, such as glucuronic acid, a fact found in the present study, where FBA was the formulation with the highest amount of glucuronic and acetic acids.

Another important fact to be highlighted is the variation of total soluble solids, as the acetic bactera in SCOBY consume sugar, converting it into organic acids. Therefore, the higher the amount of total soluble solids in a formulation, the lower the amount of acetic acid. This was observed in the present study, where the formulation that obtained the lowest amount of total soluble solids was the FBA (7.13 %;Fig. 1f), also being the formulation with the highest acetic acid production (14.67 mg/100 mL). On the other hand, FBT – the formulation with the lowest acetic acid production (5.0 mg/100 mL) – had a higher amount of total soluble solids (8.17 mg/100 g).

Black tea kombucha contains 3.23 mg/100 mL of glucuronic acid (47), a value lower than those found in all beverages in the present study (Table 2). The concentration of acetic acid in the present study was notably higher (9.18 mg/100 mL) than in black tea samples. This suggests that factors such as fermentation, type of raw material or storage conditions may have influenced the increased levels. The findings highlight significant differences in acetic acid content between the teas, emphasissing the need to further explore what drives these variations. The main metabolic characteristic of lactic acid bacteria is known as the ’primary acidification process’, referring to the carbohydrate consumption that generates acid. This action is crucial for rapid pH reduction, protecting food against decaying and pathogenic microorganisms.

Due to the fact that yeasts and lactic acid bacteria use sugars as a fermentation substrate, the predominance of lactic acid concentration is not unexpected. Simultaneously, sugar is still available in the medium, something that may have occurred in FBA, in which lactic acid concentration was 3.16 mg/100 mL.

Citric acid was found only in FBG beverage (2.60 mg/mL;Table 2). Ascorbic acid was present in FBG and FBA, ranging from 0.14 to 3.28 mg/mL, respectively. The low concentration of ascorbic acid may be associated with temperature variation, as ascorbic acid is susceptible to high temperatures, generally above 40 °C (48). Additionally, it should be considered that an industrial residue can be pressed repeatedly in order to obtain a higher pulp yield, and this single operation can influence the final bioactive content compared to the pulp.

According to the Recommended Dietary Allowances (49), the minimum amount of ascorbic acid per day required for an adult is 60 mg. This indicates that the 300 mL intake of acerola kombucha would supply approx. 16.4 % of this recommendation.

Sensory evaluation of kombucha beverage

The majority of the participants in the sensory analysis were female (60 %). Regarding age, 37 % were between 18 and 25 years old, 32 % were from 26 to 35, 18 % were from 36 to 50, 8 % were between 51 and 65 years old, and only 5 % were under 18.

Cochran's Q test result (Table 1) indicated the terms most cited by the participants. The four significant descriptors at the level of 5 % were sweet aroma, acidic taste, citric taste, and vinegar flavour, which were used to perform CATA.

Mendonça et al. (50) evaluated kombucha made from unconventional parts of Hibiscus sabdariffa L. and the samples were characterised by the sensory panel as vinegar aroma, vinegar flavour, sour taste or more viscous. Thus, similar characteristics were obtained when comparing the samples evaluated in the present study regarding vinegar flavour.

Fig. 2 shows the correlation between formulations and sensory attributes. It can be verified that the attributes most related to the FBA formulation were fermented flavour, vinegar flavour, citrus aroma, salty taste and astringent sensation.

Fig. 2 a) Analysis of the main components from check-all-that-apply (CATA) data in kombucha formulations fermented with fruit by-products, and b) histogram showing the percentages of sensory judges who identified (present) and did not identify (absent) significant sensory attributes in the CATA test at a 5 % significance level. FBA, FBG and FBT=formulation with acerola, guava and tamarind by-product, respectively
FTB-62-361-f2

Treviso et al. (51) developed kombucha separately from the yerba mate infusion and obtained a product sensorially characterised by a fermented flavour, a characteristic similar to that observed in this research.

FBA, FBG and FBT formulations have different sensory characteristics (as shown in Fig. 2), which is expected since different fruit by-products were used, and other factors were involved in the fermentation. FBA is correlated with the attribute citrus flavour, FBT with vinegar flavour and FBG with sweet taste. Although the acid taste is more related to FBG, it is also closer to the overall evaluation, indicating its preference among the samples evaluated by the tasters.

Fig. 2 shows the percentage of presence and absence of attributes with a significance of 5 %, in which sour taste and citrus taste were the attributes with the highest perception (87 %) among the tasters. After the sweet aroma attributes, with 79 %, the vinegar taste was observed at 69 %.Table 1 shows that the sweet aroma, sweet taste, and citrus flavour differed between the samples at 5 % significance level in the RATA test.

The terms bright, translucent (clear), homogeneous, sedimented, presence of bubbles, citrus aroma, acidic aroma, vinegar aroma, fermented aroma, acidic taste, sweet taste, salty taste, bitter taste, vinegar flavour, fermented flavour, astringent sensation, spicy sensation, and crimping sensation did not differ throughout the number of results among the samples evaluated.

Regarding the FBT formulation, the appearance attribute obtained a score corresponding to ‘liked it a little’, with an average of 6.0, differing significantly (p≤0.05) from the FBG and FBA formulations (Table 3), which were evaluated with averages of 7.3 and 6.8, respectively, both between ‘liked it’ and ‘liked it a little’.

Table 3 Mean values for the acceptance test of FBA, FBG and FBT formulations for the parameters of appearance, aroma, flavour, overall assessment and purchase intention of the tasters
BeverageAppearanceAromaFlavourOverall assessmentPurchase intention
FBG(7.3±1.3)a(7.2±1.4)a(7.0±1.5)a(7.0±1.5)a(3.7±1.0)a
FBT(6.0±2.0)b(6.0±1.9)b(6.2±1.9)b(6.2±2.0)b(3.3±1.0)b
FBA(6.8±1.6)a(5.6±2.1)b(6.1±18)b(6.0±1.9)b(3.2±1.1)b
Pr>F (model)0.000<0.00010.0090.0120.009

Mean values with the same letters in the same row do not differ at the 5 % significance level. FBA, FBG and FBT=formulation with acerola, guava and tamarind by-product, respectively

Regarding the aroma attribute, the FBG sample was observed to differ significantly (p≤0.05) from the FBT and FBA formulations, obtaining an average of 7.2 between ‘liked it’ and ‘liked it a lot’. The FBT and FBA formulations were rated with averages of 6.0 and 5.6, respectively, between the terms ‘neither liked nor disliked it’ and ‘liked it a little’.

The sample that received a better overall evaluation was the FBG (7.0), being close to the ‘liked it’ attribute and differing significantly (p≤0.05) from the FBT and FBA formulations, which received averages of 6.2 and 6.0, respectively, both characterised by the ‘I liked it a little’ attribute.

Formulations with different fermentative substrates will have their own acceptability characteristics, making it necessary to carry out sensory tests to confirm that the product has the potential to be accepted by potential consumers. Currently, studies involving the production of kombuchas developed with alternative substrates have demonstrated the potential associated with the acceptance of these products (52,53).

The tasters attributed the FBG formulation a higher score for the purchase intention, presenting an average of 3.7, being close to the ‘I would probably buy it’ attribute. It differs significantly (p≤0.05) from the FBT and FBA formulations, which averaged 3.3 and 3.2, respectively. Thus, both were classified with the ‘maybe I would buy it, maybe not’ attribute. Therefore, it is verified that, among the formulations studied, the one that obtained the highest score in all sensory parameters was the FBG, which may be associated with consumer preference for guava fruit.

CONCLUSIONS

Considering the chemical and physical parameters, the fermented acerola, guava and tamarind beverages have achieved satisfactory results. Taking into account the values established by current legislation, they are considered safe for human consumption from a microbiological point of view. During the evaluation of fermentation kinetics, it was observed that the pH and soluble solid content decreased with increasing acidity. Among all beverages, those obtained using acerola by-product had the highest antioxidant potential.

An excellent amount of organic acids was found in all formulations. The beverage produced from acerola by-product had the highest concentrations of glucuronic, ascorbic, lactic and acetic acids. The only formulation in which citric acid was quantified was guava by-product.

The formulation that received the highest acceptance score among the tasters was the one with the guava by-product, followed by the formulation with the tamarind by-product and the one with the acerola by-product. All samples were considered acceptable by the panellists. The importance of this work extends to the associated benefits, as it offers new food alternatives with high nutritional content and fully utilises fruit by-products.

ACKNOWLEDGEMENT

The authors are grateful for the support provided by the Food Microbiology Laboratory (LMA - Federal University of Ceará), the Bromatology Laboratory (LABROM - Federal University of Campina Grande), and Food Research and Extension Center (NUPEA - State University of Paraíba). Sincerely thanks to theLaboratory for Editing, Translating and Reviewing Academic Texts (Laboratório de Edição, Tradução e Revisão de Textos Acadêmicos - LETRARE/UFC).

Notes

[1] Financial disclosure FUNDING

The analyses proposed in the present study were funded by the National Council for Scientific and Technological Development (CNPQ). Nossa Fruta, located in Eusébio/CE, Brazil, donated the fruit co-products and pulps.

[2] Conflicts of interest CONFLICT OF INTEREST

There is no conflict of interest.

SUPPLEMENTARY MATERIAL

Supplementary material is available atwww.ftb.com.hr.

REFERENCES

1 

Ginni G, Kavitha S, Yukesh KR, Bhatia SK, Adish Kumar S, Rajkumar M, et al. Valorization of agricultural residues: Different biorefinery routes. J Environ Chem Eng. 2021;9(4):105435. https://doi.org/10.1016/j.jece.2021.105435

2 

FAO - Food and Agriculture Organization of the United Nations. Food losses and despair in Latin America and the Caribbean 23; 2016. Available from:https://www.fao.org/documents/card/en/c/I5504S

3 

Freitas LC, Barbosa JR, Da Costa ALC, Bezerra FWF, Pinto RHH, Júnior RNC. From waste to sustainable industry: How can agro-industrial wastes help in the development of new products? Resour Conserv Recycling. 2021;169:105435. https://doi.org/10.1016/j.resconrec.2021.105466

4 

Oliveira IP, Castro KN, Santos JC, Villar SBO. Diagnosis on postharvest losses of fruits and vegetables in ceasa de Juazeiro-badoi. Int J Environ Waste Manag. 2020;101:161–70.

5 

Santos Maia MN, Ramos GDM, Carvalho Antunes V. Use of agroindustrial by-products in biscuit manufacturing. Braz J Dev. 2022;8(1):1738–47 (in Portuguese). https://doi.org/10.34117/bjdv8n1-109

6 

Ribeiro da Silva LM, Figueiredo EAT, Ricardo NMPS, Vieira IGP, Figueiredo RW, Brasil IM, et al. Quantification of bioactive compounds in pulps and by-products of tropical fruits from Brazil. Food Chem. 2014;143:398–404. https://doi.org/10.1016/j.foodchem.2013.08.001 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/24054258

7 

Kapp JM, Sumner W. Kombucha: A systematic review of empirical evidence of benefit to human health. Ann Epidemiol. 2019;30:66–70. https://doi.org/10.1016/j.annepidem.2018.11.001 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/30527803

8 

Coelho RMD, Almeida AL, Amaral RQG, Mota RN, Sousa PHM. Kombucha [review]. Int J Gastron Food Sci. 2020;22:100272. https://doi.org/10.1016/j.ijgfs.2020.100272

9 

Emiljanowicz KE, Malinowska-Pańczyk E. Kombucha alternative raw materials - The review. Crit Rev Food Sci Nutr. 2020;60(19):3185–94. https://doi.org/10.1080/10408398.2019.1679714 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/31657623

10 

Silva KA, Uekane TM, de Miranda JF, Ruiz LF, da Motta JCB, Silva CB, et al. Kombucha beverage from infusion of unconventional edible plants and green tea: Characterization, toxicity, antioxidant activities and antimicrobial properties. Biocatal Agric Biotechnol. 2021;34:102032. https://doi.org/10.1016/j.bcab.2021.102032

11 

Re R, Pellegrini N, Proteggente A, Pannala A, Yang M, Rice-Evans C. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radic Biol Med. 1999;26(9-10):1231–7. https://doi.org/10.1016/S0891-5849(98)00315-3 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/10381194

12 

Rufino MSM, Alves REA, de Brito ES, de Morais SM, Sampaio CG, Pérez-Jiménez J, Saura-Calixto F. Scientific methodology: Determination of total antioxidant activity in fruits by capturing free radical DPPH. Embrapa Agroindustry Tropical-Technical Communiqué (INFOTECA-E); 2007 (in Portuguese). Available from:https://www.infoteca.cnptia.embrapa.br/bitstream/doc/426953/1/Cot127.pdf.

13 

Regulatory Instruction No. 41 of September 17, 2019. Brasilia, Brazil: Official Gazette of the Union; 2019. Available from:https://www.in.gov.br/en/web/dou/-/instrucao-normativa-n-41-de-17-de-setembro-de-2019-216803534 (in Portuguese).

14 

Adolfo Lutz Institute. Physicochemical methods for food analysis, Brazil; 2008 (in Portuguese). Available from:http://www.ial.sp.gov.br/resources/editorinplace/ial/2016_3_19/analisedealimentosial_2008.pdf.

15 

Official Methods of Analysis of AOAC International. Rockville, MD, USA: AOAC International; 2002.

16 

Manual BA. (BAM) Chapter 5: Salmonella. Silver Spring, MD, USA: US Food and Drug Administration (FDA); 2022. Available from:https://s27415.pcdn.co/wp-content/uploads/2020/01/64ER20-7/Microbial/1-Bacteriological-Analytical-Manual-BAM_Ch5_-Salmonella-_-FDA.pdf.

17 

Neffe-Skocinska K, Sionek B, Scibisz I, Kolozyn-Krajewska D. Acid contents and the effect of fermentation condition of Kombucha tea beverages on physicochemical, microbiological and sensory properties. CYTA J Food. 2017;15(4):601–7. https://doi.org/10.1080/19476337.2017.1321588

18 

Technical Note No. 48/2020/SEI/GIALI/GGFIS/DIRE4/ANVISA. Guidance document for safe food production during the Covid-19 pandemic. Brasilia, Brazil: National Health Surveillance Agency (ANVISA); 2020 (in Portuguese). Available from:https://www.gov.br/anvisa/pt-br/arquivos-noticias-anvisa/311json-file-1.

19 

Stone H, Bleibaum RN, Thomas HA, editors. Sensory evaluation practices. Amsterdam, The Netherlands: Elsevier; 2012. Available from:https://shop.elsevier.com/books/sensory-evaluation-practices/stone/978-0-12-382086-0.

20 

Meilgaard MC, Carr BT, Civille GV. Sensory evaluation techniques.Boca Raton, CA, USA: CRC Press; 1999. https://doi.org/10.1201/9781003040729 https://doi.org/10.1201/9781003040729

21 

Vidal L, Tárrega A, Antúnez L, Ares G, Jaeger SR. Comparison of correspondence analysis based on Hellinger and chi-square distances to obtain sensory spaces from check-all-that-apply (CATA) questions. Food Qual Prefer. 2015;43:106–12. https://doi.org/10.1016/j.foodqual.2015.03.003

22 

Systat Software, v. 13.2, SigmaStat, Palo Alto, CA, USA; 2024. Available from:https://grafiti.com/systat/.

23 

Agudelo A, Varela P, Fiszman S. Methods for a deeper understanding of the sensory perception of fruit fillings. Food Hydrocoll. 2015;46:160–71. https://doi.org/10.1016/j.foodhyd.2014.12.024

24 

Meyners M, Castura JC, Carr BT. Existing and new approaches for the analysis of CATA data. Food Qual Prefer. 2013;30(2):309–19. https://doi.org/10.1016/j.foodqual.2013.06.010

25 

ASSISTAT statistics and data analysis solution, v. 7.7 beta, Campina Grande, PB, Brazil; 2014. Available from:https://assistat.software.informer.com/#google_vignette.

26 

XLSTAT statistics and data analysis solution, V.4.5. Addinsoft, Long Island, NY, USA; 2024. Available from:https://www.xlstat.com.2019.

27 

Mariano-Nasser FDC, Nasser MD, Furlaneto KA, Ramos JA, Vieites RL, Pagliarini MK. Bioactive compounds in different acerola fruit cultivars. Semina. 2017;38:2505–14 (in Portuguese). https://doi.org/10.5433/1679-0359.2017v38n4Supl1p2505

28 

Chuah PN, Nyanasegaram DN, Yu KX, Razik RM, Al-Dhalli S, Kue CS, et al. Comparative methods of conventional extraction of ethanol extracts from Clinacanthus nutans leaves on antioxidant activity and toxicity. Br Food J. 2020;122(10):3139–49.https://www.doi.org/10.1108/BFJ-02-2020-0085 https://doi.org/10.1108/BFJ-02-2020-0085

29 

Carvalho FM, Martins JTA, Lima EMF, Santos HV, Pereira PAP, Pinto UM, Da Cunha LR. Pitanga and grumixama extracts: Antioxidant and antimicrobial activities and incorporation in cellulosic films against Staphylococcus aureus. Res Soc Dev. 2020;9(11):e1759119362 (in Portuguese). https://doi.org/10.33448/rsd-v9i11.9362

30 

Leonarski E, Cesca K, Zanella E, Stambuk BU, de Oliveira D, Poletto P. Production of kombucha beverage and bacterial cellulose from the by-product of acerola as raw material. Lebensm Wiss Technol. 2021;135:110075. https://doi.org/10.1016/j.lwt.2020.110075

31 

Martínez Leal J, Valenzuela Suárez L, Jayabalan R, Huerta Oros J, Escalante-Aburto A. A review on health benefits of kombucha nutritional compounds and metabolites. CYTA J Food. 2018;16(1):390–9. https://doi.org/10.1080/19476337.2017.1410499

32 

Jayabalan R, Malini K, Sathishkumar M, Swaminathan K, Yun SE. Biochemical characteristics of the tea fungus produced during kombucha fermentation. Food Sci Biotechnol. 2010;19:843–7. https://doi.org/10.1007/s10068-010-0119-6

33 

Rodrigues RDS, Machado MRG, Barboza G, Soares LS, Heberle T, Leivas YM. Physical and chemical characteristics of Kombucha based on hibiscus tea (Hibiscus sabdariffa, L.). Rio Grande do Sul, Brazil: 6th Food Security Symposium; 2018. pp. 1-6 (in Portuguese).

34 

Tanticharakunsiri W, Mangmool S, Wongsariya K, Ochaikul D. Characteristics and upregulation of antioxidant enzymes of kitchen mint and oolong tea kombucha beverages. J Food Biochem. 2021;45(1):e13574. https://doi.org/10.1111/jfbc.13574 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/33249612

35 

Velićanski AS, Cvetković DD, Markov SL, Tumbas Šaponjac VT, Vulić JJ. Antioxidant and antibacterial activity of the beverage obtained by fermentation of sweetened lemon balm (Melissa officinalis L.) tea with symbiotic consortium of bacteria and yeasts. Food Technol Biotechnol. 2014;52(4):420–9. https://doi.org/10.17113/ftb.52.04.14.3611 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/27904315

36 

Mizuta AG, de Menezes JL, Dutra TV, Ferreira TV, Castro JC, da Silva CAJ, et al. Evaluation of antimicrobial activity of green tea kombucha in two fermentation moments against Alicyclobacillus spp. Lebensm Wiss Technol. 2020;130:109641. https://doi.org/10.1016/j.lwt.2020.109641

37 

Filho AAL, de Sousa PHM, Vieira IGP, Fernandes VB, Cunha FET, Magalhaes FEA, et al. Kombucha and kefir fermentation dynamics on cashew nut beverage (Anacardium occidentale L.). Int J Gastron Food Sci. 2023;33:100778. https://doi.org/10.1016/j.ijgfs.2023.100778

38 

La Torre C, Fazio A, Caputo P, Plastina P, Caroleo MC, Cannataro R, et al. Effects of long-term storage on the radical elimination properties and phenolic content of black tea kombucha. Molecules. 2021;26(18):5474. https://doi.org/10.3390/molecules26185474 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/34576945

39 

Saints WCR, Robinson CD, Lacerda I. The characterization of kombucha black tea. 69th Annual Meeting of the SBPC; July 16, 2017; Belo Horizonte, Brazil; 2017 (in Portuguese). Available from:https://www.sbpcnet.org.br/livro/69ra/resumos/resumos/3112_197ceb2d1c03053d187fae353c9a8273d.pdf.

40 

Yang Z, Zhou F, Ji B, Li B, Luo Y, Yang L, et al. Symbiosis between microorganisms from kombucha and kefir: Potential significance to the enhancement of kombucha function. Appl Biochem Biotechnol. 2010;160:446–55. https://doi.org/10.1007/s12010-008-8361-6 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/18810658

41 

Içen H, Corbo MR, Sinigaglia M, Korkmaz BIO, Bevilacqua A. Microbiology and antimicrobial effects of kombucha, a short overview. Food Biosci. 2023;56:103270. https://doi.org/10.1016/j.fbio.2023.103270

42 

Jayabalan R, Malvaša RV, Lonçar ES, Vitas JS, Sathishkumar M. A review on kombucha tea-microbiology, composition, fermentation, beneficial effects, toxicity, and tea fungus. Compr Rev Food Sci Food Saf. 2014;13(4):538–50. https://doi.org/10.1111/1541-4337.12073 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/33412713

43 

Martínez-Leal J, Ponce-García N, Escalante-Aburto A. Recent evidence of the beneficial effects associated with glucuronic acid contained in kombucha beverages. Curr Nutr Rep. 2020;9(3):163–70. https://doi.org/10.1007/s13668-020-00312-6 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/32415557

44 

Morales D, Gutiérrez-Pensado R, Bravo FI, Muguerza B. Novel kombucha beverages with antioxidant activity based on fruits as alternative substrates. Lebensm Wiss Technol. 2023;189:115482. https://doi.org/10.1016/j.lwt.2023.115482

45 

Kim H, Hur S, Lim J, Jin K, Yang TH, Keehm IS, et al. Enhancement of the phenolic compounds and antioxidant activities of kombucha prepared using specific bacterial and yeast. Food Biosci. 2023;56:103431. https://doi.org/10.1016/j.fbio.2023.103431

46 

Grujović MŽ, Mladenović KG, Semedo‐Lemsaddek T, Laranjo M, Stefanović OD, Kocić-Tanackov SD. Advantages and disadvantages of non-starter lactic acid bacteria from traditional fermented foods: potential use as starters or probiotics. Compr Rev Food Sci Food Saf. 2022;21(2):1537–67. https://doi.org/10.1111/1541-4337.12897 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/35029033

47 

Dhakal S, Balasubramaniam VM, Ayvaz H, Rodriguez-Saona LS. Kinetic modeling of ascorbic acid degradation of pineapple juice subjected to combined pressure-thermal treatment. J Food Eng. 2018;224:62–70. https://doi.org/10.1016/j.jfoodeng.2017.12.016

48 

Budiarto R, Mubarok S, Sholikin MM, Saric DN, Khalisha A, Saric SL, et al. Vitamin C variation in citrus in response to genotypes, storage temperatures, and storage times: A systematic review and meta-analysis. Heliyon. 2024;10(8):e29125. https://doi.org/10.1016/j.heliyon.2024.e29125 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/38644865

49 

Institute of Medicine (US). Panel on dietary antioxidants and related compounds. dietary reference intakes for vitamin C, vitamin E, selenium, and carotenoids. Washington, DC, USA: National Academies Press; 2000. Available from:https://pubmed.ncbi.nlm.nih.gov/25077263/.

50 

Mendonça GR, Pinto RA, Praxedes ÉA, Abreu VKG, Dutra RP, Pereira AF. Kombucha based on unconventional parts of the Hibiscus sabdariffa L.: Microbiological, physico-chemical, antioxidant activity, cytotoxicity and sensorial characteristics. Int J Gastron Food Sci. 2023;34:100804. https://doi.org/10.1016/j.ijgfs.2023.100804

51 

Treviso RL, Sant’Anna V, Fabricio MF, Maz AYUB, Brandelli A, Hickert L. Time and temperature influence on physicochemical, microbiological, and 845 sensory profiles of yerba mate kombucha. J Food Sci Technol. 2024;61:1733–42. https://doi.org/10.1007/s13197-024-05951-z PubMed: http://www.ncbi.nlm.nih.gov/pubmed/39049923

52 

Rodríguez-Castro R, Guerrero R, Valero A, Franco-Rodriguez J, Posada-Izquierdo G. Cocoa mucilage as a novel ingredient in innovative kombucha fermentation. Foods. 2024;13(11):1636. https://doi.org/10.3390/foods13111636 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/38890865

53 

Santos DF, Leonarski E, Rossoni MA, Alves V, dos Passos Francisco CT, Pinto VZ, et al. Honey-kombucha beverage with yerba maté infusion: Development, polyphenols profile, and sensory acceptance. Int J Gastron Food Sci. 2024;36:100909. https://doi.org/10.1016/j.ijgfs.2024.100909

Appendices

Table S1 HPLC measurements of standard organic acids
Organic acidtR/minCalibration curveLinear correlationγ(linear range)/(mg/mL)
Acetic5.77y=6044469x-30333R2=0.99990.1–25.0
Glucuronic2.67y=543029x-22176R2=0.99990.5–20.0
Lactic5.11y=758060x-24574R2=0.99950.0425–4.24
Citric6.42y=106x-26252R2=0.99780.1–3.0
Ascorbic4.32y=1.65·107x-1.74·105R2=0.99720.1–5.0
Fig. S1 Flowchart of the process for the development of fermented beverages. SCOBY=symbiotic culture of bacteria and yeasts
FTB-62-361-fS1

This display is generated from NISO JATS XML with jats-html.xsl. The XSLT engine is libxslt.