Use of bacaba peel for the development of hydroelectrolytic beverages and their consumer acceptance

Baldissera, Luana; Debiasi, Bryan Wender; Agostini, Juliana da Silva; Andrighetti, Carla Regina; Sugui, Marina Mariko; Ribeiro, Elton Brito; Valladão, Dênia Mendes de Sousa

doi:10.1590/s2175-97902023e21762

Abstract

The hydroelectrolytic beverages segment has been expading its market and introducing new flavors in order to meet the demand for new products. However, experimental studies find concerns about the chemical compositions of these drinks. The aim of this study was to develop a drink without synthetic coloring or flavoring, with functional attributes based on the bacaba (Oenocarpus bacaba Mart.) peel extract. Two hydroelectrolytic drinks were developed, one hypotonic and the other isotonic, containing 0.5 and 1.0% of bacaba peel extract. Physicochemical characterization, determination of total phenolic compounds, anthocyanins, and antioxidant capacity were perfomed, in addition to color evaluation, as well as sensory analysis by means of preference tests. The developed formulations showed potential antioxidant activity and natural red coloring due to the phenolic compounds and anthocyanins present in the beverages. The sensory evaluation indicated positive acceptance by the tasters regarding the addition of the bacaba peel extract to the beverage formulations. The developed formulations demonstrated that the use of the bacaba peel is a viable option for the production of sports drinks, acting as a natural dye and offering health benefits due to its bioactive compounds.

Key words:
Anthocyanins; Oenocarpus bacaba Mart; Peel; Sports beverages

INTRODUCTION

During physical activity, it is essential to maintain water and electrolytes for body homeostasis, and for that, hydration before, during, and after exercise becomes essential. The Society of exercise and sports medicine suggests individualized hydration strategies, which must take into account the percentage of dehydration during physical activity, the intensity, the type of sport, and the individual’s organism (Thomas, Erdman, Burke, 2016Thomas DT, Erdman KA, Burke LM. American college of sports medicine joint position statement. Nutrition and athletic performance. Med Sci in Sport Exerc. 2016;48(3):543-568.; Ayotte, Corcoran, 2018Ayotte Jr D, Corcoran MP. Individualized hydration plans improve performance outcomes for collegiate athletes engaging in in-seasons training. J Int Soc Sports Nutr. 2018;15(1):1-10.).

Hydroelectrolytic beverages, also known as sports drinks, are specially designed for people who practice physical activities and aim to replenish water and electrolytes that are lost during sweating. The concentrations of substances and minerals in these drinks are similar to those found in organic fluids, leading to rapid absorption and, consequently, hydration after consumption. They are presented with hypotonic, isotonic, and hypertonic characteristics, according to the needs of each user (Thomas, Erdman, Burke, 2016Thomas DT, Erdman KA, Burke LM. American college of sports medicine joint position statement. Nutrition and athletic performance. Med Sci in Sport Exerc. 2016;48(3):543-568.; Ayotte, Corcoran, 2018Ayotte Jr D, Corcoran MP. Individualized hydration plans improve performance outcomes for collegiate athletes engaging in in-seasons training. J Int Soc Sports Nutr. 2018;15(1):1-10.; Gujar, Gala, 2014Gujar MVV, Gala MBV. Product development, biochemical and organoleptic analysis of a sports drink. IOSR J Sports Phys Educ. 2014;1(4):01-05.).

During the processing of this type of drink, dyes and synthetic flavorings with sensory characteristics similar to those of fruits are used. Experimental studies showed concerns among consumers about the chemical composition of these drinks. Also, the search for a healthier lifestyle has contributed to an interest increase in natural products in foods and beverages in order to satisfy nutritional needs, assist in the organism’s proper functioning and collaborate in the prevention against free radicals. Intending to reduce or even eliminate the use of these types of synthetic substances in food processing, researches have been seeking to implement the use of dyes extracted from natural sources. Special attention given to anthocyanins, which represent one of the most colorful classes of substances in the vegetable kingdom, being appropriate to add to beverages and food products in addition to its nutritional advantages and a strong appeal as a natural products (Kobylewski, Jacobson, 2012Kobylewski S, Jacobson MF. Toxicology of food dyes. Int J Occup Environ Health. 2012;18(3):220-246.; Gironés-Vilaplana et al., 2016Gironés-Vilaplana A, Huertas JP, Moreno DA, Periago PM, Garcia-Viguera C. Quality and microbial safety evaluation of new isotonic bevarages upon termal treatments. Food Chem. 2016;194:455-462.).

In this sense, bacaba (Oenocarpus bacaba Mart.) stands out, an Amazonian fruit, purple in color, rich in phenolic compounds, which are found both in the pulp and in the peel (Abadio Finco, Boser, Graeve, 2013Abadio Finco FD, Boser S, Graeve L. Antiproliferative activity of bacaba (Oenocarpus bacaba) and Jenipapo (Genipa americana L.) phenolic extracts: a comparison of assays. Nutr Food Sci. 2013;43(2):98-106.; Correa et al., 2019Correa BM, Baldissera L, Barbosa FR, Ribeiro EB, Andrighetti CR, da Silva Agostini J, et al. Centesimal and mineral composition and antioxidant activity of the bacaba fruit peel. Biosci J. 2019;35(2):509-517.). The use of its extract in food products and beverages is promising, as it offers an alternative to replace synthetic dyes, and can serve a public that seeks natural products, in addition to providing bioactive compounds potentially beneficial to human health, such as antioxidants that help to reduce the incidence of chronic non-communicable disorders (Dias et al., 2017Dias TR, Alves MG, Casal S, Oliveira PF, Silva BM. Promising potential of dietary (poly) phenolic compounds in the prevention and treatment of diabetes mellitus. Curr Med Chem. 2017;24(4):334-354.). Therefore, the work aim was to use the extract of the bacaba peel, a waste product, to develop hydroelectrolytic beverages with functional properties and to evaluate their physicochemical and sensory properties.

MATERIAL AND METHODS

Reagents

All reagents and solvents used in the analyses were of analytical grade. Ethyl alcohol, sodium citrate (Na₃C₆H₅O₇), sodium carbonate (Na₂CO₃) were supplied by Synth (Diadema, SP, Brazil), the citric acid by Neon (Suzano, SP, Brazil), maltodextrin by Athletica Nutrition (Matão, SP, Brazil), and the Folin-Ciocateau solution by Dinâmica (Indaiatuba, SP, Brazil). Methanol, gallic acid, 2,2-diphenyl-1-picrylhydrazyl (DPPH), 2,2′-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid) (ABTS+), and 6-hydroxy-2,5,7,8-tetramethyl chroman-2-carboxylic acid (Trolox^TM), were purchased from Sigma Aldrich Co. (St. Louis, MO, USA).

Raw Material

Bacaba fruits (Oenocarpus bacaba Mart.) were obtained in the municipality of Sinop/MT in January 2020 and taken to the Quality Control Laboratory at the Federal University of Mato Grosso, Campus of Sinop, where they were washed, sanitized, and rinsed. After the cleaning process of the fruits, the peels were removed and kept in a forced convection drying oven to eliminate the water, at approximately 40 0C for 48 hours. Afterward, peels were ground using an analytical mill and stocked at -5 0C.

Preparation of the Bacaba Peel Extract

The preparation of the bacaba peel extract for incorporation in the hydroelectrolytic beverages was performed according to Porfírio et al. (2019Porfírio MCP, Goncalves MS, Borges MV, Leite CXDS, Santos MRC, Silva AGD, et al. Development of isotonic beverage with functional attributes based on extract of Myrciaria jabuticaba (Vell) Berg. Food Sci Technol . 2019;40(3):614-620.). First, 5g of bacaba peel were ground with ethanol 70 % (v/v) (1:2 peel/ solvent) using a blender, then acidified with a citric acid solution 6% to pH 2. The obtained suspension was left under refrigeration (4° ± 1 °C) and no light incidence for 24 h. Thereafter, the extract was filtered in nylon fabric and evaporated until total elimination of the solvent in a forced convection drying oven at 40 ºC.

Preparation of the Hydroelectrolytic Beverages

The hydroelectrolytic beverage formulations were prepared in accordance with the legislation of beverage for athletes (Brasil, 2010Brasil. Anvisa. Agência Nacional de Vigilância Sanitária. Resolução RDC Nº 18, de 27 de abril de 2010. Dispõe sobre alimentos para atletas. Diário Oficial da União; Poder Executivo, de 28 de abril de 2010.), using the following ingredients: sodium chloride, sucrose, sodium citrate, maltodextrin, citric acid, and ultrapure water. All the ingredients and chemicals were food grade. For the development of the beverages, the formulations were prepared with different quantities of mineral salts and bacaba peel extract varying from 0.5 to 5 % to define the best working concentrations. The extract solubilization was difficult, which demanded that the mixture was subjected to ultrasonication (Cristófoli - Ultrasonic Cleaner, China) for 8 minutes at a frequency of 42 kHz, attempting to best dilute the added extract.

Physicochemical Characterization of the Hydroelectrolytic Beverages

The following tests were performed according to the Association of Official Analytical Chemists (AOAC, 2012AOAC Official Methods of Analysis.18nd ed. Gaithersburg, MD, USA: AOAC International, 2012.): total soluble solids (n° 932.12) acidity expressed as percent citric acid (%) (n° 937.05) and pH (n° 943.71). TSS/TTA ratio was calculated dividing the total soluble solids by the total titratable acidity values.

For the instrumental color analysis, all formulations were analyzed according to the L*, a*, and b* parameters of the colorimeter (Konica Minolta® - cr-200, Japan) using the D65 light source. L* defined the luminosity (L* = 0: black and L* = 100: white) and a* and b*, the chromaticity (+a*: red and -a*: green, +b*: yellow and -b*: blue). The hue angle (h*) and chromaticity (c*) parameters were calculated using a* and b* values through the equations 1 and 2.

h * = a r c \tan (\frac{b *}{a *})

(1)

c^{2} = \sqrt{} a^{* 2} + b^{* 2}

(2)

In order to verify the classification of the developed formulations as hydroelectrolytic beverages, their osmolality was determined with a cryoscope (ITR - MK 540, Brazil), using 2,5 mL of each formulation to read their lowering of the freezing point. Values were converted from °Hovert (°H) to Celsius (°C) by multiplying by the factor 0,965. With the cryoscopy values in °C, it was possible to use the equation 3 to calculate the osmolality (Pomeranz, Meloan, 1994Pomeranz Y, Meloan CE. Food analysis: theory and practice. Vol. 3. New York, NY, EUA: Chapman & Hall; 1994. pp 87-97.; Tarancon, Lachenmeier, 2015Tarancon JLL, Lachenmeier DW. Determination of osmolality in beer to validate claims of isotonicity. Beverages. 2015;1(2):45-54.)

\frac{m O s m o l}{k g} = \frac{Δ T c}{K c} \times 1000

(3)

where:

ΔTc = Lowering of the freezing point

Kc = Water cryoscopic constant (1.86 °C∙Kg∙mol^-1)

Determination of Total Phenolic Compounds

The total phenolic compounds (TP) assay was performed according to Georgé et al. (Georgé et al., 2005Georgé S, Brat P, Alter P, Amiot MJ. Rapid determination of polyphenols and vitamin C in plant-derived products. J Agric food chem. 2005;53(5):1370-1373.). The formulations were previously diluted and mixed with the Folin-Ciocalteu reagent solution and a sodium carbonate solution 4 % (mv^-1). All solutions were homogenized and left for 15 minutes in a water bath at 50 °C (Dellta - 210Di, Brazil). Then, the solutions were quickly cooled in cold water and the reading with a spectrophotometer (PG Instruments Ltd® - T80 UV/VIS, United Kingdom) was performed at a 760 nm wavelength.

The TP content was determined by comparing the hydroelectrolitic drinks absorbance with the standard calibration curve previously built with gallic acid (5 to 25 mgL^-1). The equation of the calibration curve was y = 0.0152x + 0.0006, where x is the gallic acid concentration. The coefficient of correlation was 0.996. Results were compared to the calibration curve and expressed as mg of EAG (gallic acid equivalent) per 100 mL of beverage.

DPPH Radical Scavenging assay

Total free radical scavenging capacity of the drinks was estimated according to Gironés-Vilaplana et al. (2016Gironés-Vilaplana A, Huertas JP, Moreno DA, Periago PM, Garcia-Viguera C. Quality and microbial safety evaluation of new isotonic bevarages upon termal treatments. Food Chem. 2016;194:455-462.), to establish the concentration of the beverages which can decrease the initial DPPH concentration by 50 % (EC₅₀), and Marecek et al. (2017Marecek V, Mikyska A, Hampel D, Cejka P, Neuwirthová J, Malachová A, et al. ABTS and DPPH methods as a tool for studying antioxidant capacity of spring barley and malt. J Cereal Sci. 2017;73:40-45.), to provide the antioxidant activity in TEAC-DPPH (Trolox Equivalent Antioxidant Capacity), values in μM of Trolox (6-Hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid) per 100 mL of sample.

The beverages were diluted to obtain different concentrations of bacaba peel extract and from the dilutions, 100 μL of each sample was transferred to screw-cap test tubes and 2900 μL of DPPH radical solution was added.

The absorbance was determined with a spectrophotometer (PG Instruments® - T80 UV/VIS, United Kingdom), at the wavelength of 515 nm, after keeping the solutions for 30 minutes in the absence of light.

ABTS Radical Scavenging assay

The ABTS (2,2’-azino-bis (3-ethylbenzothiazolin) 6-sulfonic acid) method was performed according to Re et al. (1999Re R, Pellegrini N, Proteggente A, Pannala A, Yang M, Rice-Evans C. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radical Biol Med. 1999;26(9/10):1231-1237.) modified by Marecek et al. (2017Marecek V, Mikyska A, Hampel D, Cejka P, Neuwirthová J, Malachová A, et al. ABTS and DPPH methods as a tool for studying antioxidant capacity of spring barley and malt. J Cereal Sci. 2017;73:40-45.). The absorbance was measured in a spectrophotometer at a wavelength of 734 nm, 6 minutes after adding the sample to the ABTS solution. The results were expressed as TEAC-ABTS (Trolox Equivalent Antioxidant Capacity) in µmol of TEAC / 100 mL of drink.

Determination of Total Anthocyanin content

The determination of the total anthocyanins was carried out by the official method (Lee, Durst, Wrolstad, 2005Lee J, Durst RW, Wrolstad RE. Determination of total monomeric anthocyanin pigment contento f fruit juices, beverages, natural colorants, and wines by the pH differential method: Collaborative study. J AOAC Int. 2005;88(5):1269-1278.), which is based on the differential pH method of Fuleki and Francis (1968Fuleki T, Francis FJ. Quantitative methods for anthocyanins. 2. Determination of total anthocyanin and degradation index for cranberry juice. J Food Sci. 1968;33(1):78-83.) and considers the structural transformations undergone by anthocyanins at different pHs. Measurements were also performed at pH 1.0 and 4.5 at 510 nm (maximum absorption wavelength of anthocyanins at these pHs) and at 700 nm to correct possible light scattering. The results were expressed in milligrams of cyn-3-glu (equivalent in cyanidin-3-glucoside) per liter (L) of beverage and calculated by the equation 4:

m g L^{- 1} c y d - 3 - g l u = \frac{A \times M W \times D F \times 10^{3}}{\times l}

(4)

where A (absorbance) = (A_520nm - A_700nm) pH 1.0 - (A_520nm - A_700nm) pH 4.5;

MW (molecular weight) = 449.2 gmol^-1 for cyanidin-3-glucoside (cyd-3-glu);

DF = dilution factor;

l = pathlength in cm;

ɛ = 26 900 molar absorptive coefficient in mol ^-1 L cm^-1 for cyd-3-glu; and

10³ = factor for conversion from g to mg.

Sensory evaluation Analysis

The sensory evaluation analysis followed the methodology proposed by Lyon, Francombe, Hasdell (2012Lyon D, Francombe MA, Hasdell TA. Guidelines for sensory analysis in food product development and quality control. Vol 2. London, UK: Chapman & Hall. 2012.). The consumer acceptance test was performed with 100 tasters, volunteers, not trained, of both genders, from the university environment, who were invited to participate in the sensorial test. The analysis was performed individually, under white light equivalent to daylight. Each taster received three samples of the beverages (formulation 0.5 %, formulation 1.0 %, and control (extract-free)) in disposable transparent cups coded with a three-digit number at ± 12 °C. Water was offered to the tasters after each evaluation to cleanse the palate.

The tasters evaluated the mouthfeel, color, scent, flavor, and acceptance (overall impression), using the hedonic scale of nine points (9 - Extremely liked; 8 - Liked very much; 7 - Modestly liked; 6 - Slightly liked; 5 - Indifferent; 4 - Slightly disliked; 3 - Modestly disliked; 2 - Disliked very much and 1 - Extremely disliked).

Statistical Analysis

For color and sensory analysis, analysis of variance (ANOVA) was performed and significant differences between the mean values were determined by the Tukey multiple comparison test with 95% significance (p <0.05). The results were presented with the mean value ± standard deviation using the OriginPro software v8 (OriginLab^©).

Ethics Committee

This work was previously submitted to the Comitê de Ética em Pesquisa - CEP (Ethics Committee in Research) of the Federal University of Mato Grosso, according to the Resolution 196/96 from the Conselho Nacional de Saúde (National Health Council) and approved under CAAE 66639117.9.0000.8097.

RESULTS AND DISCUSSION

The bacaba peel extract presented purple color and yield of 16.5%. The beverages were prepared by dissolving the ingredients (Table I) and the bacaba peel extract in water. After dissolution, some formulations showed turbid aspect and oil on their surfaces, because the bacaba fruit, as well as the bacaba peel, have great amounts of lipids (Correa et al., 2019Correa BM, Baldissera L, Barbosa FR, Ribeiro EB, Andrighetti CR, da Silva Agostini J, et al. Centesimal and mineral composition and antioxidant activity of the bacaba fruit peel. Biosci J. 2019;35(2):509-517.). Therefore, after their filtration of the formulations, only two formulations (0.5 and 1.0 %) showed limpid aspect and no oil on the surface while the others (formulations 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5, and 5.0 %) were rejected due to their turbidity, not meeting the specifications for hydroelectrolytic beverages (Brasil, 2010Brasil. Anvisa. Agência Nacional de Vigilância Sanitária. Resolução RDC Nº 18, de 27 de abril de 2010. Dispõe sobre alimentos para atletas. Diário Oficial da União; Poder Executivo, de 28 de abril de 2010.). Consequently, three formulations were established for the study: control (without extract) and the ones with 0.5 and 1.0 % of extract.

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TABLE I
Ingredients used in the preparation of the hydroelectrolytic beverage formulations containing 0.5 % and 1.0 % of bacaba peel extract and control

The citric acid added to the formulations had the purpose of reducing their pH values making them more acidic, since it is one of the main characteristics of this type of drink (Brasil, 2010Brasil. Anvisa. Agência Nacional de Vigilância Sanitária. Resolução RDC Nº 18, de 27 de abril de 2010. Dispõe sobre alimentos para atletas. Diário Oficial da União; Poder Executivo, de 28 de abril de 2010.). 0.4% of citric acid was added to both formulations, however, the greater amount of extract in formulation 1% contributted to this acidity, which may allow a reduction in the percentage of acid added to the formulation.

The physicochemical characterization parameters of the beverages are presented in Table II. According to Valadao et al. (2019Valadao NK, Shimoda SY, Jory JC, Fratassi GC, Petrus RR. Stability of a dairy-based electrolyte replenishment beverage. Food Sci Technol . 2019;39(4):824-829.), this kind of beverage is classified as acidic (pH <4.0), which favors microbiological stability and, consequently, safety for consumption. In addition, these pH values are aligned with those obtained in other studies on the development of hydroelectrolytic drinks, such as Galvão et al. (2020Galvão LMV, Sousa MDM, Nascimento AMDCB, Souza BVCD, Nunes LCC. Evaluation of shelf life of isotonic beverage enriched with cajuína. Food Sci Technol. 2020; AHEAD.), with pH values ranging from 2.88 to 3.66. The control formulation showed a higher pH (4.25) and less acidity because it did not contain the bacaba peel extract.

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TABLE II
Results of the physicochemical characterization of the beverage formulations developed with 0.5 % and 1.0 % of bacaba peel extract and control

Total titratable acidity results, expressed in percentage of citric acid in the beverages, varied in formulation 0.5 % to formulation 1.0 %. Santos, Alves and Lima (2013Santos ESM, Alves RM, Lima CS. Elaboração tecnológica e aceitação sensorial de bebida isotônica orgânica de tangerina (Citrus reticulata Blanco). Rev Inst Adolfo Lutz. 2013;72(1):87-92 (In Portuguese).) evaluated three formulations of organic tangerine isotonic beverages and the pH values obtained ranged from 3.1 to 3.3 and the total titratable acidity values between 0.13 and 0.21%, showing variations in the results obtained for the same type of beverage, corroborating the results obtained in this study.

The °Brix of beverages expresses the amount of total soluble solids (TSS) in the product, which presents a relevant relationship with the quality of the final product. Considering the base formulation was the same for all beverage samples, the values obtained show that the addition of bacaba peel extract interfered with the amount of total soluble solids and, consequently, it also interfered in the acceptance of the drink, as the presented values indicate the presence of mineral salts, acids, and sugar, substances that can provide a sweeter and more pleasant flavor to the product. These values also contributed to the osmolality since the higher the concentration of total soluble solids, the greater is the osmotic pressure caused by these electrolytes in beverages.

The relation between the TSS and TTA, denominated ratio, is an indicator used to determine the quality of the balance between the sweet and acid flavors. The higher the ratio value, the greater is the feeling of sweetness to the product. For Stampanoni (1993Stampanoni C. Influence of acid and sugar contend on sweetness, sourness and the flavour profile of beverages and sherbets. Food Qual Prefer. 1993;4(3):169-176.), it is important to perform this analysis in beverage samples, since the high acidity in this type of beverage may lead to product refusal. The ratio considers the sugar content, directly affecting the sensory evaluation of the products. The TSS/TTA ratio was higher in the control formulation than in the 0.5 % and 1.0 % beverages, thus proving it to be sweeter than the drinks containing the extract. Considering the same amount of sugar was added to all formulations, these results are probably related to the lower acidity in the control formulation, due to the absence of bacaba peel extract.

According to Brazilian law (2010), the osmotic values found in this study demonstrate that the formulation with 0.5 % of extract is classified as hypotonic and the drink with 1.0 % is isotonic.

Isotonic beverages contain electrolytes balanced with the body fluid, once their osmolality is the same as blood plasma. These beverages are used to increase energy and replace fluid and minerals the body uses during physical exercise. On the other hand, hypotonic beverages have lower osmolality than blood plasma, being adequate for athletes who perform moderate activities, without too much physical exhaustion and loss of water through sweating (Suzuki et al., 2013Suzuki K, Hashimoto H, Oh T, Ishijima T, Mitsuda H, Peake JM, et al. The effects of sports drink osmolality on fluid intake and immunoendocrine responses to cycling in hot conditions. J Nutr Sci Vitaminol. 2013;59(3):206-212.).

Nutrients such as carbohydrates, minerals, and medium-chain triglycerides influence osmolality (Brouns, Kovacs, 1997Brouns FJPH, Kovacs E. Functional drinks for athletes. Trends Food Sci Technol. 1997;8(12):414-421.) and can be added or removed from a formulation, but in this case, the different amounts of bacaba peel extract added also collaborated with the type of drink developed.

The total phenolic and anthocyanin contents and antioxidant activity of the hydroelectrolytic beverages developed with concentrations of 0.5 % and 1.0 % of bacaba peel extract are presented in Table III. The control formulation presented no activity.

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TABLE III
Total phenol and anthocyanin contents and antioxidant activity of the hydroelectrolytic beverage formulations devel ped in concentrations of 0.5 % and 1.0 % of bacaba peel extract

The results of total phenol contents show that the 1.0 % drink had a greater amount of phenolic compounds as a consequence of the greater amount of bacaba peel extract added to it. These results corroborate the study by Correa et al. (2019Correa BM, Baldissera L, Barbosa FR, Ribeiro EB, Andrighetti CR, da Silva Agostini J, et al. Centesimal and mineral composition and antioxidant activity of the bacaba fruit peel. Biosci J. 2019;35(2):509-517.) who analyzed the phenolic compounds in bacaba fruit peel and found the value of 42.07 mg EAG g-1. Nascimento et al. (2019Nascimento RAD, Andrade EL, Santana EB, Ribeiro NFDP, Costa CML, Faria LJGD. Bacaba powder produced in spouted bed: an alternative source of bioactive compounds and energy food product. Braz J Food Technol. 2019;22:e2018229.) evaluated the bacaba pulp powder produced using a drying technique called spouted bed and found expressive phenolic compounds concentrations, 376.43 mg EAG /100 mL. The study shows that pulp drying using spouted bed reduces the degradation of bioactive compounds, which is common in pulps due to its high perishability. Moreover, the bacaba powder obtained by spouted bed drying provided higher contents of bioactive compounds than other existing products and by-products described in the literature and used in the industry as sources of these constituents. The total anthocyanin results agree with the values found for total phenolic compounds. Since this group includes a wide variety of phytochemicals, they are divided into different classes, including anthocyanins which are phenolic compounds from the flavonoid class (Shahidi, Ambigaipalan, 2015Shahidi F, Ambigaipalan P. Phenolics and polyphenolics in foods, beverages and spices: Antioxidant activity and health effects: A review. J Funct Foods. 2015;18:820-897.). Gironés-Vilaplana et al. (2016Gironés-Vilaplana A, Huertas JP, Moreno DA, Periago PM, Garcia-Viguera C. Quality and microbial safety evaluation of new isotonic bevarages upon termal treatments. Food Chem. 2016;194:455-462.) found lower values when studying isotonic beverages based on açaí and lemon and açaí juice, obtaining values of 0.74 and 0.93 mg/100 mL, respectively.

The presence of anthocyanins contributed to the antioxidant activity and coloration of the beverages. This demonstrates the possibility of taking advantage of the color of fruits and develop isotonic beverages with bioactive compounds since anthocyanins in acidic pH are more stable and have an intense red color. The difference in the anthocyanins concentration influenced the intensity of the drinks’ red color.

According to the results shown in Table III, the EC₅₀ values obtained with DPPH radical scavenging assay for beverages containing 0.5 % and 1.0 % of bacaba peel extract showed no significant difference between them (p>0.05). This result could be explained by the fact the extract incorporated to the drinks was the same, having only its concentration changed. In order to verify how the concentration of the beverage contributed to the antioxidant activity, the TEAC-DPPH was calculated. When evaluating beverages using the TEAC-ABTS method, it was possible to observe that there was no difference between both methods, that is, the found results agree with those obtained by the TEAC-DPPH analysis.

The antioxidant activity of the beverage is directly correlated to the phenolic compounds and anthocyanins in the bacaba peel extract (Table III). These results demonstrate that the higher the concentration of bacaba peel extract added, the greater is the antioxidant activity performed by the drink. These results add interesting chemical and biological properties to the drink, enabling it to collaborate in the organism’s protection against free radicals that are frequently produced, including by intense exercises, which have recently been highlighted as a critical biochemical variable linked to oxidative stress and negative redox balance (Medina, 2012Medina S, Doménguez-Perles R, Cejuela-Anta R, Villaño D, Martínez-Sanz JM, Gil P, et al. Assessment of oxidative stress markers and prostaglandins after chronic training of triathletes. Prostag Oth Lipid M. 2012;99(3-4):79-86.). On that matter, hydroelectrolytic drinks with antioxidant capacity can help to regulate some oxidative biochemical disorders caused by intense exercising, turning them into functional drinks with innovative characteristics that differentiate them from commercial hydroelectrolytic drinks.

Color is a crucial sensory characteristic that triggers the first response of a consumer in contact with the product. The application of the bacaba peel extract in the drinks provided an attractive natural red appearance for those who consume this type of beverage.

Regarding the instrumental color (Table IV), beverages showed a L* value below white, indicating that they were dark-colored, and the formulation with 0.5 % of extract was lighter-colored than the formulation with 1.0 %, due to the lower amount of bacaba peel extract (p < 0.0005).

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TABLE IV
Mean values of the color coordinates of the developed beverages with 0.5% and 1.0 % of bacaba peel extract and control

The coordinate a* results presented a significant difference when comparing the two formulations containing the extract (p < 0.0005) however, both showed positive values indicating their tendency towards red. The formulation with 1.0 % of extract had a more intense red color than the formulation with 0.5% because of the greater amount of extract and, consequently, anthocyanins. The b* parameter (p < 0.0005) presented positive values, indicating a yellowish color in the evaluated beverages. On the other hand, h* (p = 0.00114), which represents the hue, showed low values, highlighting that the beverages exhibited tones more inclined to red.

Chromacity (C*) had significant difference (p < 0.005) for the formulations and between formulations 0.5% and 1% (p < 0.005). The high values for this coordinate indicate the formulations had bright and saturated colors. The calculation of the variable ∆E* (color difference values) was performed by the equation ∆E*=√ (∆L*)2 + (∆a*)2 + (∆b*)2 and the value obtained was 9.20. According to Gonnet (1988Gonnet JF. Color effects of co-pigmentation of antocyanins revisited 1: a colorimetric definition using the Cielab scale. Food chem. 1988;63(3):409-415.), C* values above 1.0 are already enough to indicate perceptive visual color changes between two samples.

Based on these parameters, it can be inferred that the beverages are translucent and red which is what is expected for products based on bacaba peel since the fruit shows dark coloration, originated from the presence of anthocyanins. The results of the sensory analysis on sample preference are presented in Table V.

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TABLE V
Sensory attributes (mean value ± standard deviation) of the hydroelectrolytic beverage formulations: Control, 0.5 % and 1.0 %

Overall, considering the attributes analyzed such as mouth-feel and flavor, the beverages’ results did not show any significant difference between them (p = 0.5527 and 0.76251), indicating that the addition of the extract did not interfere in mouth-feel and flavor, maintaining the typical characteristics of a hydroelectrolytic drink with acidic characteristics, for physical activity.

Regarding the color attributes, it was noted that the two formulations containing bacaba peel extract showed a significant difference when compared to the control drink (p <0.0001) with mean values greater than 6.0 which, according to the hedonic scale, means slightly-moderately liked it (Nascimento et al., 2019Nascimento RAD, Andrade EL, Santana EB, Ribeiro NFDP, Costa CML, Faria LJGD. Bacaba powder produced in spouted bed: an alternative source of bioactive compounds and energy food product. Braz J Food Technol. 2019;22:e2018229.).

This attribute is an important parameter and should be determinant for acceptance and preference in this type of product. Synthetic dyes are the most used but there are associations between the consumption of these dyes and diseases such as cancer and allergies (Gukowsky et al., 2018Gukowsky JC, Xie T, Gao S, Qu Y, He L. Rapid identification of artificial and natural food colorants with surface enhanced Raman spectroscopy. Food Control. 2018;92:267-275.). On the other hand, the bacaba peel is a natural product, with antioxidant properties, that has the additional advantage of using a product that would go to waste.

Concerning the scent attribute, the drink containing 0.5% of extract obtained a higher mean value (7.25 = moderately liked) when compared to the control drink (p <0.05) and the one with a greater amount of extract, which obtained less than 7.0 on the hedonic scale. It should be noted that the sensory attributes such as taste, color, and aroma are influenced, respectively, by the chemical composition, amount of sugar, total solids, acidity, and pH. In this case, the results were expected since the beverages present the same composition, varying only the amount of the extract, which proved not to interfere in the global acceptance since the beverages didn’t present a significant difference (p = 0.185).

Moreover, the results indicated positive acceptance by the tasters regarding the addition of bacaba peel extract. In this way, the consumption of these drinks can provide carbohydrates and also phenolic compounds, capable of regulating biochemical disturbances caused by acute intensity exercises and help to improve the performance of those who practice sports. Thus, the developed beverages, in addition to not containing artificial dyes and flavorings, contain bioactive compounds and are economically viable products since they use a raw material that would go to waste, making itself an economically viable product. Obtaining ingredients from this source can help diversify end markets for fruit suppliers while making good economic use of different parts of the plants.

CONCLUSIONS

It was possible to develop two hydroelectrolytic beverages without artificial dyes, one hypotonic (0.5 %) and the other isotonic (1.0 %), from the bacaba peel extract, a waste product. Both beverages have bioactive compounds, which contribute to the antioxidant activity and can be useful in the redox balance during the acute and intense phases of exercise and restore the electrolyte balance of athletes after prolonged stress.

The developed beverages were well accepted by the tasters and can be worked on to improve their sensory attributes. Thus, the use of bacaba peel in beverage processing can be another alternative for the use of residues from the agro-industry. Besides that, the use of bacaba peel contributes to the reduction of organic waste production, in addition to presenting low toxicity and low cost.

ACKNOWLEDGEMENTS

To the Foundation of Support to Research of the State of Mato Grosso (FAPEMAT - Process number 224179/2015) for the project’s financial support and for the scholarship granted, to the Federal University of Mato Grosso (UFMT) for the structural support and endorsement to have this study executed.

REFERENCES

Abadio Finco FD, Boser S, Graeve L. Antiproliferative activity of bacaba (Oenocarpus bacaba) and Jenipapo (Genipa americana L.) phenolic extracts: a comparison of assays. Nutr Food Sci. 2013;43(2):98-106.
AOAC Official Methods of Analysis.18nd ed. Gaithersburg, MD, USA: AOAC International, 2012.
Ayotte Jr D, Corcoran MP. Individualized hydration plans improve performance outcomes for collegiate athletes engaging in in-seasons training. J Int Soc Sports Nutr. 2018;15(1):1-10.
Brasil. Anvisa. Agência Nacional de Vigilância Sanitária. Resolução RDC Nº 18, de 27 de abril de 2010. Dispõe sobre alimentos para atletas. Diário Oficial da União; Poder Executivo, de 28 de abril de 2010.
Brouns FJPH, Kovacs E. Functional drinks for athletes. Trends Food Sci Technol. 1997;8(12):414-421.
Correa BM, Baldissera L, Barbosa FR, Ribeiro EB, Andrighetti CR, da Silva Agostini J, et al. Centesimal and mineral composition and antioxidant activity of the bacaba fruit peel. Biosci J. 2019;35(2):509-517.
Dias TR, Alves MG, Casal S, Oliveira PF, Silva BM. Promising potential of dietary (poly) phenolic compounds in the prevention and treatment of diabetes mellitus. Curr Med Chem. 2017;24(4):334-354.
Fuleki T, Francis FJ. Quantitative methods for anthocyanins. 2. Determination of total anthocyanin and degradation index for cranberry juice. J Food Sci. 1968;33(1):78-83.
Galvão LMV, Sousa MDM, Nascimento AMDCB, Souza BVCD, Nunes LCC. Evaluation of shelf life of isotonic beverage enriched with cajuína. Food Sci Technol. 2020; AHEAD.
Georgé S, Brat P, Alter P, Amiot MJ. Rapid determination of polyphenols and vitamin C in plant-derived products. J Agric food chem. 2005;53(5):1370-1373.
Gironés-Vilaplana A, Huertas JP, Moreno DA, Periago PM, Garcia-Viguera C. Quality and microbial safety evaluation of new isotonic bevarages upon termal treatments. Food Chem. 2016;194:455-462.
Gonnet JF. Color effects of co-pigmentation of antocyanins revisited 1: a colorimetric definition using the Cielab scale. Food chem. 1988;63(3):409-415.
Gujar MVV, Gala MBV. Product development, biochemical and organoleptic analysis of a sports drink. IOSR J Sports Phys Educ. 2014;1(4):01-05.
Gukowsky JC, Xie T, Gao S, Qu Y, He L. Rapid identification of artificial and natural food colorants with surface enhanced Raman spectroscopy. Food Control. 2018;92:267-275.
Kobylewski S, Jacobson MF. Toxicology of food dyes. Int J Occup Environ Health. 2012;18(3):220-246.
Lee J, Durst RW, Wrolstad RE. Determination of total monomeric anthocyanin pigment contento f fruit juices, beverages, natural colorants, and wines by the pH differential method: Collaborative study. J AOAC Int. 2005;88(5):1269-1278.
Lyon D, Francombe MA, Hasdell TA. Guidelines for sensory analysis in food product development and quality control. Vol 2. London, UK: Chapman & Hall. 2012.
Marecek V, Mikyska A, Hampel D, Cejka P, Neuwirthová J, Malachová A, et al. ABTS and DPPH methods as a tool for studying antioxidant capacity of spring barley and malt. J Cereal Sci. 2017;73:40-45.
Medina S, Doménguez-Perles R, Cejuela-Anta R, Villaño D, Martínez-Sanz JM, Gil P, et al. Assessment of oxidative stress markers and prostaglandins after chronic training of triathletes. Prostag Oth Lipid M. 2012;99(3-4):79-86.
Nascimento RAD, Andrade EL, Santana EB, Ribeiro NFDP, Costa CML, Faria LJGD. Bacaba powder produced in spouted bed: an alternative source of bioactive compounds and energy food product. Braz J Food Technol. 2019;22:e2018229.
Pomeranz Y, Meloan CE. Food analysis: theory and practice. Vol. 3. New York, NY, EUA: Chapman & Hall; 1994. pp 87-97.
Porfírio MCP, Goncalves MS, Borges MV, Leite CXDS, Santos MRC, Silva AGD, et al. Development of isotonic beverage with functional attributes based on extract of Myrciaria jabuticaba (Vell) Berg. Food Sci Technol . 2019;40(3):614-620.
Re R, Pellegrini N, Proteggente A, Pannala A, Yang M, Rice-Evans C. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radical Biol Med. 1999;26(9/10):1231-1237.
Santos ESM, Alves RM, Lima CS. Elaboração tecnológica e aceitação sensorial de bebida isotônica orgânica de tangerina (Citrus reticulata Blanco). Rev Inst Adolfo Lutz. 2013;72(1):87-92 (In Portuguese).
Shahidi F, Ambigaipalan P. Phenolics and polyphenolics in foods, beverages and spices: Antioxidant activity and health effects: A review. J Funct Foods. 2015;18:820-897.
Stampanoni C. Influence of acid and sugar contend on sweetness, sourness and the flavour profile of beverages and sherbets. Food Qual Prefer. 1993;4(3):169-176.
Suzuki K, Hashimoto H, Oh T, Ishijima T, Mitsuda H, Peake JM, et al. The effects of sports drink osmolality on fluid intake and immunoendocrine responses to cycling in hot conditions. J Nutr Sci Vitaminol. 2013;59(3):206-212.
Tarancon JLL, Lachenmeier DW. Determination of osmolality in beer to validate claims of isotonicity. Beverages. 2015;1(2):45-54.
Thomas DT, Erdman KA, Burke LM. American college of sports medicine joint position statement. Nutrition and athletic performance. Med Sci in Sport Exerc. 2016;48(3):543-568.
Valadao NK, Shimoda SY, Jory JC, Fratassi GC, Petrus RR. Stability of a dairy-based electrolyte replenishment beverage. Food Sci Technol . 2019;39(4):824-829.

Publication Dates

Publication in this collection
28 Apr 2023
Date of issue
2023

History

Received
09 Sept 2021
Accepted
24 Mar 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Abadio Finco FD, Boser S, Graeve L. Antiproliferative activity of bacaba (Oenocarpus bacaba) and Jenipapo (Genipa americana L.) phenolic extracts: a comparison of assays. Nutr Food Sci. 2013;43(2):98-106.

[2] AOAC Official Methods of Analysis.18nd ed. Gaithersburg, MD, USA: AOAC International, 2012.

[3] Ayotte Jr D, Corcoran MP. Individualized hydration plans improve performance outcomes for collegiate athletes engaging in in-seasons training. J Int Soc Sports Nutr. 2018;15(1):1-10.

[4] Brasil. Anvisa. Agência Nacional de Vigilância Sanitária. Resolução RDC Nº 18, de 27 de abril de 2010. Dispõe sobre alimentos para atletas. Diário Oficial da União; Poder Executivo, de 28 de abril de 2010.

[5] Brouns FJPH, Kovacs E. Functional drinks for athletes. Trends Food Sci Technol. 1997;8(12):414-421.

[6] Correa BM, Baldissera L, Barbosa FR, Ribeiro EB, Andrighetti CR, da Silva Agostini J, et al. Centesimal and mineral composition and antioxidant activity of the bacaba fruit peel. Biosci J. 2019;35(2):509-517.

[7] Dias TR, Alves MG, Casal S, Oliveira PF, Silva BM. Promising potential of dietary (poly) phenolic compounds in the prevention and treatment of diabetes mellitus. Curr Med Chem. 2017;24(4):334-354.

[8] Fuleki T, Francis FJ. Quantitative methods for anthocyanins. 2. Determination of total anthocyanin and degradation index for cranberry juice. J Food Sci. 1968;33(1):78-83.

[9] Galvão LMV, Sousa MDM, Nascimento AMDCB, Souza BVCD, Nunes LCC. Evaluation of shelf life of isotonic beverage enriched with cajuína. Food Sci Technol. 2020; AHEAD.

[10] Georgé S, Brat P, Alter P, Amiot MJ. Rapid determination of polyphenols and vitamin C in plant-derived products. J Agric food chem. 2005;53(5):1370-1373.

[11] Gironés-Vilaplana A, Huertas JP, Moreno DA, Periago PM, Garcia-Viguera C. Quality and microbial safety evaluation of new isotonic bevarages upon termal treatments. Food Chem. 2016;194:455-462.

[12] Gonnet JF. Color effects of co-pigmentation of antocyanins revisited 1: a colorimetric definition using the Cielab scale. Food chem. 1988;63(3):409-415.

[13] Gujar MVV, Gala MBV. Product development, biochemical and organoleptic analysis of a sports drink. IOSR J Sports Phys Educ. 2014;1(4):01-05.

[14] Gukowsky JC, Xie T, Gao S, Qu Y, He L. Rapid identification of artificial and natural food colorants with surface enhanced Raman spectroscopy. Food Control. 2018;92:267-275.

[15] Kobylewski S, Jacobson MF. Toxicology of food dyes. Int J Occup Environ Health. 2012;18(3):220-246.

[16] Lee J, Durst RW, Wrolstad RE. Determination of total monomeric anthocyanin pigment contento f fruit juices, beverages, natural colorants, and wines by the pH differential method: Collaborative study. J AOAC Int. 2005;88(5):1269-1278.

[17] Lyon D, Francombe MA, Hasdell TA. Guidelines for sensory analysis in food product development and quality control. Vol 2. London, UK: Chapman & Hall. 2012.

[18] Marecek V, Mikyska A, Hampel D, Cejka P, Neuwirthová J, Malachová A, et al. ABTS and DPPH methods as a tool for studying antioxidant capacity of spring barley and malt. J Cereal Sci. 2017;73:40-45.

[19] Medina S, Doménguez-Perles R, Cejuela-Anta R, Villaño D, Martínez-Sanz JM, Gil P, et al. Assessment of oxidative stress markers and prostaglandins after chronic training of triathletes. Prostag Oth Lipid M. 2012;99(3-4):79-86.

[20] Nascimento RAD, Andrade EL, Santana EB, Ribeiro NFDP, Costa CML, Faria LJGD. Bacaba powder produced in spouted bed: an alternative source of bioactive compounds and energy food product. Braz J Food Technol. 2019;22:e2018229.

[21] Pomeranz Y, Meloan CE. Food analysis: theory and practice. Vol. 3. New York, NY, EUA: Chapman & Hall; 1994. pp 87-97.

[22] Porfírio MCP, Goncalves MS, Borges MV, Leite CXDS, Santos MRC, Silva AGD, et al. Development of isotonic beverage with functional attributes based on extract of Myrciaria jabuticaba (Vell) Berg. Food Sci Technol . 2019;40(3):614-620.

[23] Re R, Pellegrini N, Proteggente A, Pannala A, Yang M, Rice-Evans C. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radical Biol Med. 1999;26(9/10):1231-1237.

[24] Santos ESM, Alves RM, Lima CS. Elaboração tecnológica e aceitação sensorial de bebida isotônica orgânica de tangerina (Citrus reticulata Blanco). Rev Inst Adolfo Lutz. 2013;72(1):87-92 (In Portuguese).

[25] Shahidi F, Ambigaipalan P. Phenolics and polyphenolics in foods, beverages and spices: Antioxidant activity and health effects: A review. J Funct Foods. 2015;18:820-897.

[26] Stampanoni C. Influence of acid and sugar contend on sweetness, sourness and the flavour profile of beverages and sherbets. Food Qual Prefer. 1993;4(3):169-176.

[27] Suzuki K, Hashimoto H, Oh T, Ishijima T, Mitsuda H, Peake JM, et al. The effects of sports drink osmolality on fluid intake and immunoendocrine responses to cycling in hot conditions. J Nutr Sci Vitaminol. 2013;59(3):206-212.

[28] Tarancon JLL, Lachenmeier DW. Determination of osmolality in beer to validate claims of isotonicity. Beverages. 2015;1(2):45-54.

[29] Thomas DT, Erdman KA, Burke LM. American college of sports medicine joint position statement. Nutrition and athletic performance. Med Sci in Sport Exerc. 2016;48(3):543-568.

[30] Valadao NK, Shimoda SY, Jory JC, Fratassi GC, Petrus RR. Stability of a dairy-based electrolyte replenishment beverage. Food Sci Technol . 2019;39(4):824-829.

Ingredients	Control	Formulation 0.5%	Formulation 1.0%
Citric acid	0.40g	0.40g	0.40g
Sodium citrate	0.40g	0.40g	0.40g
Sodium Chloride	0.30g	0.30g	0.30g
Bacaba peel	-	10g	20g
Maltodextrin	26g	26g	26g
Sucrose	36g	36g	36g
Water q.s	1.0L	1.0L	1.0L

Parameters Evaluated	Control	Formulation 0.5%	Formulation 1.0%
pH	4.25 ± 0.01	3.36 ± 0.01	3.25 ± 0.01
Total Titratable Acidity (TTA) (%)	0.02 ± 0.01	0.27 ± 0.05	0.44 ± 0.02
Brix (TSS)	6.10 ± 0.01	6.50 ± 0.01	6.80 ± 0.01
TSS/TTA Ratio	329.70	23.50	15.30
Osmolality (mOsmolKg^-1)	154.3 ± 0.14	254 ± 0.13	287 ± 0.31

Parameters evaluated	Formulation 0.5 %	Formulation 1.0 %
Phenols (mg EAG/ 100 mL)	8.42 ± 0.36^a	15.93 ± 0.10^b
Anthocyanins (mg/100 mL)	6.74 ± 1.99 ^a	11.8 ± 0.59 ^b
EC50 (mgL^-1)	31.71 ± 2.20 ^a	33.34 ± 3.52 ^a
TEAC-DPPH (µM/100 mL)	90.0 ± 1.48 ^a	46.17 ± 2.25 ^b
TEAC-ABTS (µM / 100 mL of sample)	90.75 ± 3.021 ^a	47.03 ± 2.55 ^b

Color coordinate	Control	Formulation 0.5 %	Formulation 1.0 %
L*	68.30 ± 0.41^a	45.60 ± 0.49^b	39.40 ± 0.49^c
a*	0.58 ± 0.02^c	17.40 ± 0.47^b	23.10 ± 0.42^a
b*	1.43 ± 0.01^c	13.80 ± 0.41^b	17.50 ± 0.37^a
h*	67.90 ± 0.47^a	38.80 ± 0.11^b	37.10 ± 0.16^c
C*	1.54 ± 0.01^c	21.60 ± 0.41^b	29.00 ± 0.55^a

Sensory Attributes	Formulation
Sensory Attributes	Control	Formulation 0.5 %	Formulation 1.0 %
Month-feel	6.22 ± 1.67^a	6.27 ± 1.89^a	6.55 ± 1.72^a
Color	5.53 ± 1.78^b	7.14 ± 1.33^a	6.73 ± 1.41^a
Scent	6.44 ± 1.54^b	7.25 ± 1.78^a	6.92 ± 1.74^a
Flavor	5.67 ± 1.80^a	6.07 ± 2.04^a	6.16 ± 2.03^a
Acceptance (Overall impression)	4.92 ± 1.81^b	5.72 ± 1.91^a	5.77 ± 1.80^a