Acessibilidade / Reportar erro

Characterization and identification of bioactive compounds in agro-food waste flours

Abstract

One of the recurrent problems of the agroindustry sector is the incorrect disposal of waste because of the complexity of the material, moisture, among other factors. Waste is not used in tonnage, but is systematically used. Examples of residues are malt bagasse and cassava peel, produced in large quantities in the brewing industry and flour production, respectively. In this context, the objective of this study was to evaluate bioactive compounds of flours produced from agroindustry waste to potentiate their use as an ingredient rich in antioxidants. The flours produced from agroindustry waste were evaluated for phenolic compounds, total carotenoids, antioxidant activity, and the attainment of phenolic profiles and fingerprints by paper spray mass spectrometry. It was possible to identify a broad class of compounds in both flours, such as phenolic acids, flavonoids, among others. The flours can be possibly included in food commodities or packaging formulation since they are natural antioxidants, thus adding value to these products and reducing environmental issues. However, further analysis is needed to ensure bioavailability as well as food safety.

Keywords:
waste; fragments; phenolics; cassava peel; malt bagasse


INTRODUCTION

Waste generation in the agroindustry sector has been a recurring problem that compromises the environment. Tons of plant waste is produced annually by different industrial segments. Due to the large volume generated, transport difficulty, low added value, and high propensity for microbiological growth, these residues are destined mainly for supplementation in animal feed, used as raw material for combustion and/or disposed of in landfills. Their underutilization is due to the difficulty in treating them to be used again by the industry.11 Franca, A. S.; Oliveira, L. S.; Nova Science Publishers 2009, 8, 155. The big challenge is to provide alternative, sustainable destinations in quantily for waste.22 Mirabella, N.; Castellani, V.; Sala, S.; J. Cleaner Prod. 2014, 65, 28. This amount includes the by-products of the exploitation of starch sources, as well as waste from the brewing industry, which, for having peculiar characteristics, has gained space as the raw material of different commodities, at a time when the appeal for natural products by a large part of the population is increasing.33 Ayala-Zavala, J. F.; Vega-Veja; Dominguez, C. R.; Palafox, H.; Food Res. Int. 2011, 44, 1866.

The progressive increase in production in the brewing industry leads to many residues such as malt bagasse.44 http://www.mdic.gov.br/comercio-exterior/estatisticas-de-comercio-exterior/comex-vis/frame-ppe?ppe=3108, accessed in june 2020.
http://www.mdic.gov.br/comercio-exterior...
Barley malt bagasse is formed after malt germination and mashing, in the must filtration stage, generating 14 to 20 kg of this residue for every 100 liters of beer produced.55 Santos, M. S.; Ribeiro, F. M.; Cervejas e Refrigerantes, São Paulo: CETESB, 2005, p. 58.,66 Verde, A. A.; Cucolo, M. C.; Oliveira, M. L. C.; Cvalieri, F. L. B.; Andreazzi, M. A.; Emanuelli, I. P.; Revista Valore 2019, 4, 84. The destination of malt bagasse varies according to the region, and it can be directed to several applications: human food, energy production (charcoal, biogas, and direct combustion), incorporation in construction materials, paper production, adsorbents, and mainly for use as animal feed.77 Mussato, S. I.; Dragone, G.; Roberto, I. C.; J. Cereal Sci. 2006, 43, 1.,88 Carvalho, S.; Frasson, M. F.; Simões, F. S. B.; Bernardes, G. M. C.; Simões, R. R.; Griebler, L.; Pellegrin, A. C. R. S.; Menegon, A. M.; Deponti, L. S.; Severo, M. M.; Mello, V. L.; Arquivo Brasileiro de Medicina Veterinária e Zootecnia 2017, 69, 742.

Studies conducted by the Brazilian Institute of Geography and Statistics highlighted that in 2019 the Brazilian cassava production reached 18.9 million tons, and 60% of the harvested roots are used in flour production with a high residue generation.99 https://sidra.ibge.gov.br/home/lspa/brasil, accessed in January 2022.
https://sidra.ibge.gov.br/home/lspa/bras...
,1010 Bianchi, V. L. D.; Cereda, M. P.; Energia na Agricultura 1999, 14, 34. During the various processing stages, dry and wet residues are generated, most of which are dried, discarded directly in the soil, or used as animal feed.1010 Bianchi, V. L. D.; Cereda, M. P.; Energia na Agricultura 1999, 14, 34.

Cassava peel, a material rich in fibers, minerals, and sugars, has been used as animal feed and energy production.1111 Dourado, D. P.; Macedo, D. A.; Tonani, F. L. E.; Muraishi, C. T.; Revista Integralização Universitária 2017, 12, 22.,1212 Loureiro, A. C.; Soares, J. V. S.; Chaar, J. S.; Hidalgo, A. F.; Souza, L. S. S.; Pereira, A. M.; Appl. Sci. Rev. 2020, 4, 606. Malt bagasse contains proteins and fibers (cellulose, hemicellulose, and lignin) in its composition in addition to extractives and ash in smaller proportions.1313 Saraiva, B. R..; Vital, A. C. P.; Anjo, F. A.; Cesaro, E.; Matumoto-Pintro, P. T.; Pubsaúde 2018, 1, a009. The search for bioactive compounds comprises an appealing possibility to aggregate value to these underused residues, some studies report this possibility.1414 Mohd-Asharuddin, S.; Othman, N.; Zin, N. S. M.; Tajarudin, H. A.; MATEC Web of Conferences, EDP Sciences, 2017, 06012.

15 da Rosa Almeida, A.; Geraldo, M. R. F.; Ribeiro, L. F.; Silva, M. V.; Maciel, M. V. D. O. B.; Haminiuk, C. W. I.; Acta Scientiarum. Technol. 2017, 39, 269

16 Fărcaş, A. C.; Socaci, S. A.; Mudura, E.; Dulf, F. V.; Vodnar, D. C.; Tofană, M.; Salanţă, L. C.; Brew. Technol. (2017), doi: 10.5772/intechopen.69231.
https://doi.org/10.5772/intechopen.69231...

17 Souto, L. R. F.; Caliari, M.; Soares, M. S.; Fiorda, F. A.; Garcia, M. C.; Food Sci.Technol. 2016, 37, 19.
-1818 Júnior, L. F. C.; Valente, G. D. F. S.; Silva, M. D. M. C.; Brazilian Journal of Development 2020, 6, 74010. Bioactive compounds can promote health benefits due to their antioxidant and antibacterial activities and their capability to stimulate the immune system, among other properties.1919 Moraes, F. P.; Rev. Eletronica Farm. 2007, 3, 109.

High-performance liquid chromatography (HPLC) has been currently used to identify bioactive compounds.2020 Silva, M.; Freitas, L.; Souza, A.; Araújo, R.; Lacerda, I.; Pereira, H.; Augusti, R.; Melo, J.; J. Braz. Chem. Soc. 2019, 30, 1034. HPLC provides qualitative and quantitative analyses, but with some disadvantages, such as the need for time-consuming sample preparation and chromatographic run steps and high costs.2121 Eça, K. S.; Machado, M. T. C.; Hubinger, M. D.; Menegalli, F. C.; J. Food Sci. 2015, 80, C2389. Recent developments in ambient ionization mass spectrometry may be an alternative to overcome these limitations, especially analysis time and reagents. These techniques have been used to obtain fingerprints of several complex matrices via ultra-fast, low-cost, and clean analyses.2222 Zhi-Ping, Z.; Xiao-Ning, L.; Ya-Jun, Z.; Chin. J.; Anal. Chem. 2014, 42, 145.,2323 Guo, Y.; Gu, Z.; Liu, X.; Liu, J.; Ma, M.; Chen, B.; Wang, L.; Phytochem. Anal. 2017, 28, 344. Among ambient ionization techniques, paper spray mass spectrometry (PS-MS), developed by Wang et al.,2424 Wang, H.; Liu, J.; Cooks, R. G.; Ouyang, Z.; Angew. Chem., Int. Ed. 2010, 122, 889. stood out for its remarkable ability to quickly and efficiently generate fingerprints from complex samples.2020 Silva, M.; Freitas, L.; Souza, A.; Araújo, R.; Lacerda, I.; Pereira, H.; Augusti, R.; Melo, J.; J. Braz. Chem. Soc. 2019, 30, 1034.,2525 Silva, V. D. M.; Arquelau, P. B. F.; Silva, M. R.; Augusti, R.; Melo, J. O. F.; Fante, C. A.; Quim. Nova 2020, 43, 579.

26 Silva, V. D. M.; Macedo, M. C. C.; Santos, A. N.; Silva, M. R.; Augusti, R.; Lacerda, I. C. A.; Melo, J. O. F.; Fante, C. A.; Rapid Commun. Mass Spectrom. 2020b, 34, 8883.

27 Minighin, E. C.; Anastácio, L. R.; Melo, J. O. F.; Labanca, R. A.; Res. Society Develop. 2020, 9, e760986116.
-2828 e Loyola, A. C. F.; Silva, V. D.; Silva, M. R.; Rodrigues, C. G.; Dos Santos, A. N.; Melo, J. O.; Fante, C. A.; J. Braz. Chem. Soc. 2021, 32, 953.

The present manuscript aims to analyze, detect and identify bioactive compounds in some agroindustry residues, namely cassava peel, and malt bagasse. The prospect for their possible uses in new market segments, with the consequent reduction of their disposal in nature, is also part of the objectives of this work.

EXPERIMENTAL

For the production of flours, cassava peel and malt bagasse purchased at the local market in Sete Lagoas, MG, Brazil, between May and June 2018 were used as raw materials. For the preparation of the flours, the residues were dried in a cabin dryer with forced air circulation (Sparrow, PE 60 Model, Petrópolis, Brazil) at 70 °C for 12 hours. The dry material was crushed in a Walita Food Processor (750 W), with the grinder attachment for 2 minutes at speed 1 (9500 rpm). Cassava peel (CPF) and malt bagasse (MBF) flours were placed in amber glass jars and stored at - 18 °C (in a freezer) until use, in order to avoid moisture and loss of bioactive compounds.The other reagents used were of analytical grade.

Tannins

The detection of tannins in the flours was performed according to the vanillin/HCl method with absorbance reading in a spectrophotometer (Micronal AJX-1900 model, São Paulo) at 500 nm.2929 Price, M. L.; Hagerman, A. E.; J. Agric. Food Chem. 1980, 28, 459. Tannin concentration in the samples was determined by building a standard curve with different catechin concentrations. The absorbance of the sample was replaced in the equation Y = 0.268x + 0.007, with R2 0.99, where x is tannins concentration expressed in mg Catechin Eq/g, on dry basis and Y is the absorbance.

Total Carotenoids

After extraction with acetone and partition with petroleum ether, the total carotenoids were quantified by spectrophotometry at 450 nm. The total carotenoid (C) content was calculated using the equation C = 100 [( A x V x 10-4)/(E1% x M)], where: A = Absorbance at 450 nm, multiplied by the dilution factor; V = Sample volume (25 mL); E1% = Extinction coefficient of β-carotene in petroleum ether = 2592, M = Sample mass (g). The results were expressed in mg of carotenoids per gram of dry basis.3030 Rodriguez-Amaya D. B.; J. Food Compos. Anal. 1996, 196.

Extraction

The extraction was done according to Rufino et al.3131 Rufino, M. S. M.; Alves, R. E.; Brito, E. S.; Pérez-Jiménez, J.; Saura-Calixto, F.; Filho, J. M.; Food Chem. 2010, 121, 996. to evaluate the total phenolic content, antioxidant activity, phenolic profile and to acquire the PS mass spectra. For this, 2.5 g of sample were weighed, and 10 mL of methanol/water (50:50, v/v) were added to a 50-mL Falcon tube. After 1 h at room temperature protected from the light, the tubes were centrifuged (Sigma, 2K15, Germany) at 2800 G for 22 min, and the supernatant was recovered. After, 10 mL of acetone/water (70:30, v/v) were added to the residue, with new incubation and centrifugation under the same conditions described. Both supernatants were mixed, and the volume was completed to 25 mL with distilled and deionized water.

Total phenolic compounds and antioxidant activity

The total phenolic compounds of the flours were determined by the Folin-Ciocalteu method according to the methodology of SAHAN, CANSEV, and GULEN.3232 Sahan, Y.; Cansev, A.; Gulen, H.; Food Sci. Biotechnol. 2013, 22, 613. Antioxidant activity was evaluated by the methods FRAP and ABTS and DPPH according to the official method 2012.04 described by AOAC.3131 Rufino, M. S. M.; Alves, R. E.; Brito, E. S.; Pérez-Jiménez, J.; Saura-Calixto, F.; Filho, J. M.; Food Chem. 2010, 121, 996.,3333 AOAC. Association of Official Analytical Chemists. Official methods of analysis of the Association of Official Analytical Chemists, 19th ed., Ed. William Horwitz: Gaithersburg, 2012.

Phenolic profile

The determination of the profile of the main phenolic compounds present in the flours (CPF and MBF) was performed according to the chromatographic method described by Eça et al.,2121 Eça, K. S.; Machado, M. T. C.; Hubinger, M. D.; Menegalli, F. C.; J. Food Sci. 2015, 80, C2389. with some modifications. The extract was filtered with a 0.22 μm nylon syringe filter and placed in vials for automatic injection of 1 μL in ultra-performance liquid chromatography (Waters, Acquity UPLC® Class, Milford, Massachusetts, USA) equipped with diode-array UV detector, quaternary pump, online degasser, and automatic sampler. The data were processed using Empower® software. The chromatographic conditions were as follows: Acquity UPLC® BEH C18 column (2.1 x 100 mm; 1.7 μm, Waters, Milford, Massachusetts, USA), a constant flow rate of 0.3 mL.min-1 with two mobile phases (A = acetonitrile and B = water: formic acid, 99.75:0.25). The standards diluted in water (gallic acid, catechin, and chlorogenic acid) were run for 17 min in isocratic elution mode of 5:95 v/v (A:B). For the standards diluted in methanol (caffeic acid, ellagic acid, quercetin and rutin), the following elution gradients were applied: from 0 to 8 min = 8:92 (A:B); from 8 to 14 min = 15:85; and from 14 to 22 min = 25:75. The spectra were obtained at 253, 271, 279, 322, and 372 nm. Analytical curves were constructed for each standard within the concentration range from 13.75 to 220 ppm, obtaining R2 greater than 0.999. The results obtained were expressed in μg g-11 Franca, A. S.; Oliveira, L. S.; Nova Science Publishers 2009, 8, 155. of extract.

PS-MS

The analysis of the chemical profile of the samples was performed using a LCQ Fleet mass spectrometer (ThermoScientific, São José, CA, USA) equipped with a paper spray ionization source. The flour samples were analyzed in positive and negative ionization modes. A triangle-shaped chromatographic paper (1.5 cm height and 1.0 cm width) was cut, held by copper support, and positioned 0.5 cm away from the mass spectrometer inlet. This system was connected to a high-voltage source from the mass spectrometer via a copper wire. Finally, 2.0 μL of the flour extracts were applied to the central part of the triangle, 40.0 μL of methanol were transferred to chromatographic paper, and the high-voltage applied. The analyses of each flour were performed in triplicate for the positive and negative ionization modes.2020 Silva, M.; Freitas, L.; Souza, A.; Araújo, R.; Lacerda, I.; Pereira, H.; Augusti, R.; Melo, J.; J. Braz. Chem. Soc. 2019, 30, 1034.,3434 Campelo, F. A.; Henriques, G. S.; Simeone, M. L. F.; Queiroz, V. A. V.; Silva, M. R.; Augusti, R.; Melo, J. O. F.; Lacerda, I. C. A.; Araujo, R. L. B.; J. Braz. Chem. Soc. 2020, 31, 788.,3535 Silva, E. B. M.; Augusti, R.; Melo, J. O. F.; Takahashi, J. A.; Araújo, R. L. B.; Quim. Nova 2020, 43, 319.

The following MS conditions were applied: source voltage of +4.0 kV (positive ionization mode) and-3.0 kV (negative ionization mode); capillary tension of 40 V; transfer tube temperature of 275 °C; tube lens voltage of 120 V; and mass range of m/z 100 to 1000 (positive and negative ionization modes). The ions and their fragments were identified based on data described in the literature. The collision energies used to fragment the compounds ranged from 15 to 40 mu (manufacturer unit).

Statistical analysis

First, the normality of the results and the homogeneity of variances were evaluated. The mean results of the variables were analyzed by the Student’s t-test (for normal distribution) or by the Wilcoxon-Mann-Whitney test (for no normal distribution) with a significance of 5%. All tests were performed with the assistance of the SPSS 15.0 software for Windows (SPSS Inc., USA).

RESULTS AND DISCUSSION

The contents of condensed tannins (T), total carotenoids (C), and total phenolics (P) are shown in Table 1. Note that the content of these compounds remarkably differed between the flours. The T content was higher for CPF than MBF, while an opposite result is observed for C and P.

Table 1
Condensed tannins (T), total carotenoids (C), and total phenolics (P) in cassava peel (CPF) and malt bagasse (MBF) flours on a dry basis

Tannins (T) are secondary metabolites of polyphenolic nature, responsible for the characteristics normally attributed to plants that contain high levels of these substances, such as astringency and the ability to precipitate proteins.3636 Haslam, E.; J. Nat. Prod. 1996, 59, 205. The higher T content in CPF, when compared to MBF, is possibly because CPF was obtained directly from washed cassava peel and subjected to the drying process. Although several antinutritional factors are attributed to tannins, many studies show the beneficial effects upon ingestion in moderate amounts (10 to 40 g/kg of dry matter). They can act as a natural antioxidant, with anticarcinogenic, antihypertensive, and fungicide actions.3636 Haslam, E.; J. Nat. Prod. 1996, 59, 205.

37 Brandes.; Feitas, E. A. G.; Agropecuária Catarinense 1992, 5, 44.
-3838 De Angelis, R. C.; Importância de alimentos vegetais na proteção da saúde: fisiologia da nutrição protetora e preventiva de enfermidades degenerativas, Atheneu: São Paulo, 2001, p. 295.

Carotenoids, in addition to playing a fundamental role in plant metabolism, also have several effects health, such as increased immune response, inhibition of cell proliferation, and reduced risk of degenerative diseases.3939 Sentanin, M. A.; Amaya, D. B. R.; Food Sci. Technol. 2007, 27, 13.,4040 Murillo, E.; Giuffrida, D.; Menchaca, D.; Dugo, P.; Torre, G.; Meléndez-Martinez, A. J.; Mondello, L.; Food Chem. 2013, 140, 825. Gonçalves et al.,4141 Gonçalves Silva, R. M.; Figueiredo, P. A.; Peixoto, E. C. T.; De M.; Silva, L. P.; Biosci. J. 2013, 30, 556. found 450 μg of carotenoid in 100 g of fresh white cassava, a value higher than that found in the present study arising from a cassava peel residue (Table 1). MBF (333.85 μg carotenoid/100 g) stood out compared to CPF, which may be related to the presence of other ingredients, in addition to malt, added during beer production.66 Verde, A. A.; Cucolo, M. C.; Oliveira, M. L. C.; Cvalieri, F. L. B.; Andreazzi, M. A.; Emanuelli, I. P.; Revista Valore 2019, 4, 84. These residues showed similar carotenoid contents (for MBF) when compared to those found for frozen açaí pulp (0.21 to 3.84 mg/100 g) of different brands in a study conducted by dos Santos et al.4242 Dos Santos, G. M.; Maia, G. A.; Souza, P. H. M.; Costa, J. M. C.; Figueiredo, R. W.; Prado, G. M.; Arch. Latinoam. Nutr. 2008, 58, 187. These data once again show the potential for using these residues as a source of bioactive compounds. The CPF and MBF flours showed significant levels of total phenolic contents (230.83 and 549.41 mg GA Eq/100 g of dry matter, respectively). These results were higher than those found in ripe ‘Prata’ banana peel (183.85 mg GA Eq/100 g),2525 Silva, V. D. M.; Arquelau, P. B. F.; Silva, M. R.; Augusti, R.; Melo, J. O. F.; Fante, C. A.; Quim. Nova 2020, 43, 579. thus showing that both residues are potential sources for extracting such compounds. A study conducted with malt bagasse by Da Costa4343 Da Costa, G. M.; Silva, V. R. O.; Louzada, M. H.; Queiroz, I. C.; Ciên. Tecnol. Meio Ambiente 2020, 1, 11. found 140 mg of GA/100 g in MBF, lower than the value reported herein (549.41 mg GA Eq/100 g of dry matter), a difference that may be related to the recipe for producing beer in each process. Socaci et al.,4444 Socaci, S. A.; Fărcaş, A. C.; Diaconeasa, Z. M.; Dan Vodnar, D. C.; Rusu, B.; Tofană, M.; J. Cereal Sci. 2018, 80, 180. found total phenolic contents (determined by the Folin-Ciocalteu method) ranging from 40.97 mg GA/100 g to 114.23 mg GA/100 g for malt bagasse, lower than those of the present study.

Regarding the total antioxidant activity determined by the ABTS, FRAP, and DPPH methods (Table 2), the flours showed higher values by the ABST method. There was no significant difference between the CPF and MBF flours (5% significance) only by the ABTS method. By ABTS and FRAP, the antioxidant activity was higher for MBF, while by DPPH, the highest activity was observed for CPF. These data may indicate that the compounds extracted from MBF probably contain molecules that react with ABTS and FRAP free radicals. Conversely, the CPF extract probably contains more strongly reducing molecules capable of reacting with DPPH free radicals.

Table 2
Antioxidant activity by ABTS, FRAP, and DPPH methods in CPF and MBF on a dry basis (DB)

Regarding antioxidant activity, the ABTS and DPPH methods were the ones that best suited the studied residues. The samples being tested are better free radical scavengers. There was no significant difference between the residues by the ABTS method, and the values were close to those observed by Loyola et al.,2828 e Loyola, A. C. F.; Silva, V. D.; Silva, M. R.; Rodrigues, C. G.; Dos Santos, A. N.; Melo, J. O.; Fante, C. A.; J. Braz. Chem. Soc. 2021, 32, 953. in flour of green banana peels dried in an oven at 70 °C. Some vegetables analyzed by Tiveron4646 Tiveron, A. P.; Tese de Doutorado, Universidade Federal de São Paulo, Brasil, 2010. showed lower values than those found in the residues analyzed here, such as zucchini (12.7 μmol L-1 Trolox/g), beetroot (11.1 μmol L-1 Trolox/g), and carrot (8.1 μmol L-1 Trolox/g). Hence, the residues (CPF and MBF) showed considerable antioxidant activity by the ABTS assay, being even better than some vegetables frequently consumed.

In the method based on the free-radical scavenging principle (DPPH), CPF stood out, but its value was lower than that observed in green banana peels and higher than that found in pineapple residues.2828 e Loyola, A. C. F.; Silva, V. D.; Silva, M. R.; Rodrigues, C. G.; Dos Santos, A. N.; Melo, J. O.; Fante, C. A.; J. Braz. Chem. Soc. 2021, 32, 953.,4545 Infante, J.; Selani, M. M.; Toledo, N. M. V.; Silveira-Diniz, M. F.; Alencar, S. M.; Spoto, M. H. F.; Braz. J. Food Nutr. 2013, 24, 87. (Table 2)

In the phenolic profile (Table 3), gallic acid was found in high amounts in both flours, followed by catechin, rutin, chlorogenic acid, and caffeic acid. Ellagic acid and quercetin were not detected in any of the two flours studied, and in MBF only gallic and caffeic acids were detected. The extraction yield of phenolic compounds correlate with various factors, such as the extraction method and solvent used.4747 Chirinos, R.; Pedresch, R.; Rogez, H.; Larondelle, Y.; Campos, D.; Ind. Crops Prod. 2013, 47, 145. This fact explains why some compounds were not determined by chromatography but were detected by PS-MS.

Table 3
Phenolic profile (mg/100 g on dry basis) in cassava peel (CPF) and malt bagasse (MBF) residue flours

Full scan PS-MS (fingerprints)

Figure 1 exemplifies PS-MS spectra of the flours (CPF and MBF) in their positive and negative modes, providing information on the samples’ chemical composition. The results reveal the presence of organic acids, phenolic compounds, flavonoids, quinones, triterpenoids, amino acids, sugars, and other ionizable compounds.

Figure 1
PS-Ms in the positive (+) and negative (-) ion modes

Negative mode (-)

Table 4 displays the possible compounds detected in the negative ionization mode for the CPF and MBF flours: organic acids, phenolic compounds, and flavonoids.

Table 4
Identification of ions detected in the PS(-)-MS of cassava peel (CPF) and malt bagasse (MBF) flours

Organic acids

Cassava peel flour showed more ions classified as organic acids compared to malt bagasse flour. This difference probably occurs because the malt residue goes through more industrial processes than cassava peel, which only goes through the cleaning, sanitizing, and peeling processes. In MBF, octadecanedioic acid (m/z 313) was possibly detected based on the ion of m/z 295 arising upon its mass-selection and fragmentation. For CPF, eight organic acids were identified, including some fatty acids and citric acid. The ion of m/z 353, with a fragment of m/z 179, was identified as chlorogenic acid. Citric (m/z 191) and malic (m/z 133) acids were also observed in the PS(-)-MS, and they have also been found in studies with green and ripe banana peel residue flours.2525 Silva, V. D. M.; Arquelau, P. B. F.; Silva, M. R.; Augusti, R.; Melo, J. O. F.; Fante, C. A.; Quim. Nova 2020, 43, 579.,2828 e Loyola, A. C. F.; Silva, V. D.; Silva, M. R.; Rodrigues, C. G.; Dos Santos, A. N.; Melo, J. O.; Fante, C. A.; J. Braz. Chem. Soc. 2021, 32, 953.

Phenolic Compounds

The ions of m/z 170, with a fragment of m/z 125, and m/z 179, with a fragment of m/z 135,4747 Chirinos, R.; Pedresch, R.; Rogez, H.; Larondelle, Y.; Campos, D.; Ind. Crops Prod. 2013, 47, 145. correspond to gallic acid and caffeic acid, respectively, were also detected in both flours. In CPF, the following phenolic acids were identified: ellagic acid (m/z 302 and fragment of m/z 284) and ferulic acid (m/z 193 and fragment of m/z 134). Note that the chromatographic method used could not detect ellagic acid for this study (Table 3).

Flavonoids

The flavonoid group contains the highest number of substances identified in the negative ionization mode. Flavonoids are secondary metabolites of plants, and their intake is linked to preventive action against chronic non-communicable diseases, with antioxidant, anti-inflammatory and anticarcinogenic potential and cardiovascular protection capacity.4848 Queiroz, V. A. V.; Moraes, E. M.; Schaffert, R. E.; Moreira, A. V.; Ribeiro, S. M. R.; Martino, H. S. D.; Rev. Bras. Milho Sorgo 2011, 10, 180. In MBF, the ion of m/z 431 was identified as vitexin based on its main fragment (m/z 311). For CPF, additional flavonoids were identified: catechin (m/z 289 and fragment of m/z 245), quercetin (m/z 301 and fragment of m/z 151), and rutin (m/z 609 and fragment of m/z 301). Flours obtained from green banana peel residue and loquat leaf extract also contained rutin and catechin.2828 e Loyola, A. C. F.; Silva, V. D.; Silva, M. R.; Rodrigues, C. G.; Dos Santos, A. N.; Melo, J. O.; Fante, C. A.; J. Braz. Chem. Soc. 2021, 32, 953.,3535 Silva, E. B. M.; Augusti, R.; Melo, J. O. F.; Takahashi, J. A.; Araújo, R. L. B.; Quim. Nova 2020, 43, 319. Rutin and quercetin have pharmacological properties such as anti-inflammatory action and antioxidant power, acting on free radicals responsible for degenerative diseases and cell aging and death.4949 Famacognosia: da planta ao medicamento; Simões, C. M. O., org.; 6th ed., Editora da UFSC e UFRGS: Porto Alegre, 2007.

Positive mode (+)

Table 5 presents the possible compounds detected in the positive ionization mode for the MBF and CPF flours.

Table 5
Identification of ions detected in the PS(+)-MS of cassava peel (CPF) and malt bagasse (MBF) flours

Amino acids

CPF showed the presence of L-arginine, identified in its protonated form of m/z 175, with a fragment of m/z 70.2020 Silva, M.; Freitas, L.; Souza, A.; Araújo, R.; Lacerda, I.; Pereira, H.; Augusti, R.; Melo, J.; J. Braz. Chem. Soc. 2019, 30, 1034.

Flavonoids

Only CPF showed molecules that could be identified as flavonoids in the positive mode. The ion of m/z 595 (fragment of m/z 287) was identified as tiliroside (kaempferol-3-O-(6-p-coumaroyl)-glycoside), a glycosidic flavonoid with anti-inflammatory and antioxidant properties.5050 Sala, A.; Recio, M. C.; Giner, R.M.; Manez, S.; Tournier, H.; Schinella, G.; Rios, J. L., J. Pharm. Pharmacol. 2002, 54, 365.

Sugars

From the profile of ions displayed in Table 5, the ion of m/z 381, observed exclusively in the PS(+)-MS of CPF, was identified as the adduct of potassium of sucrose.

CONCLUSIONS

Even though they are agro-industrial residues,considered as products of low added value, the two flours evaluated herein (CPF and MBF) showed remarkable antioxidant activities by the ABTS method. In CPF, the obtained values of phenolic acids (gallic acid, chlorogenic acid, caffeic acid, rutin, and catechin) were higher than those found in MBF. The same trend was revealed by PS-MS data, which indicated organic acids, sugar, and phenolic acids, among other compounds, in the composition of such flours. The PS-MS method proved to be a fast and straightforward technique to obtain the fingerprint of such residues, enabling the identification of several compounds confirmed by high-performance liquid chromatography analyses described in the literature. These residues have the potential for application in the food industry, given the presence of bioactive compounds. However, further studies are required regarding the safety and bioavailability of these active compounds found.

REFERENCES:

  • 1
    Franca, A. S.; Oliveira, L. S.; Nova Science Publishers 2009, 8, 155.
  • 2
    Mirabella, N.; Castellani, V.; Sala, S.; J. Cleaner Prod 2014, 65, 28.
  • 3
    Ayala-Zavala, J. F.; Vega-Veja; Dominguez, C. R.; Palafox, H.; Food Res. Int 2011, 44, 1866.
  • 4
    http://www.mdic.gov.br/comercio-exterior/estatisticas-de-comercio-exterior/comex-vis/frame-ppe?ppe=3108, accessed in june 2020.
    » http://www.mdic.gov.br/comercio-exterior/estatisticas-de-comercio-exterior/comex-vis/frame-ppe?ppe=3108
  • 5
    Santos, M. S.; Ribeiro, F. M.; Cervejas e Refrigerantes, São Paulo: CETESB, 2005, p. 58.
  • 6
    Verde, A. A.; Cucolo, M. C.; Oliveira, M. L. C.; Cvalieri, F. L. B.; Andreazzi, M. A.; Emanuelli, I. P.; Revista Valore 2019, 4, 84.
  • 7
    Mussato, S. I.; Dragone, G.; Roberto, I. C.; J. Cereal Sci. 2006, 43, 1.
  • 8
    Carvalho, S.; Frasson, M. F.; Simões, F. S. B.; Bernardes, G. M. C.; Simões, R. R.; Griebler, L.; Pellegrin, A. C. R. S.; Menegon, A. M.; Deponti, L. S.; Severo, M. M.; Mello, V. L.; Arquivo Brasileiro de Medicina Veterinária e Zootecnia 2017, 69, 742.
  • 9
    https://sidra.ibge.gov.br/home/lspa/brasil, accessed in January 2022.
    » https://sidra.ibge.gov.br/home/lspa/brasil
  • 10
    Bianchi, V. L. D.; Cereda, M. P.; Energia na Agricultura 1999, 14, 34.
  • 11
    Dourado, D. P.; Macedo, D. A.; Tonani, F. L. E.; Muraishi, C. T.; Revista Integralização Universitária 2017, 12, 22.
  • 12
    Loureiro, A. C.; Soares, J. V. S.; Chaar, J. S.; Hidalgo, A. F.; Souza, L. S. S.; Pereira, A. M.; Appl. Sci. Rev 2020, 4, 606.
  • 13
    Saraiva, B. R..; Vital, A. C. P.; Anjo, F. A.; Cesaro, E.; Matumoto-Pintro, P. T.; Pubsaúde 2018, 1, a009.
  • 14
    Mohd-Asharuddin, S.; Othman, N.; Zin, N. S. M.; Tajarudin, H. A.; MATEC Web of Conferences, EDP Sciences, 2017, 06012.
  • 15
    da Rosa Almeida, A.; Geraldo, M. R. F.; Ribeiro, L. F.; Silva, M. V.; Maciel, M. V. D. O. B.; Haminiuk, C. W. I.; Acta Scientiarum. Technol. 2017, 39, 269
  • 16
    Fărcaş, A. C.; Socaci, S. A.; Mudura, E.; Dulf, F. V.; Vodnar, D. C.; Tofană, M.; Salanţă, L. C.; Brew. Technol. (2017), doi: 10.5772/intechopen.69231.
    » https://doi.org/10.5772/intechopen.69231
  • 17
    Souto, L. R. F.; Caliari, M.; Soares, M. S.; Fiorda, F. A.; Garcia, M. C.; Food Sci.Technol. 2016, 37, 19.
  • 18
    Júnior, L. F. C.; Valente, G. D. F. S.; Silva, M. D. M. C.; Brazilian Journal of Development 2020, 6, 74010.
  • 19
    Moraes, F. P.; Rev. Eletronica Farm. 2007, 3, 109.
  • 20
    Silva, M.; Freitas, L.; Souza, A.; Araújo, R.; Lacerda, I.; Pereira, H.; Augusti, R.; Melo, J.; J. Braz. Chem. Soc 2019, 30, 1034.
  • 21
    Eça, K. S.; Machado, M. T. C.; Hubinger, M. D.; Menegalli, F. C.; J. Food Sci 2015, 80, C2389.
  • 22
    Zhi-Ping, Z.; Xiao-Ning, L.; Ya-Jun, Z.; Chin. J.; Anal. Chem 2014, 42, 145.
  • 23
    Guo, Y.; Gu, Z.; Liu, X.; Liu, J.; Ma, M.; Chen, B.; Wang, L.; Phytochem. Anal. 2017, 28, 344.
  • 24
    Wang, H.; Liu, J.; Cooks, R. G.; Ouyang, Z.; Angew. Chem., Int. Ed. 2010, 122, 889.
  • 25
    Silva, V. D. M.; Arquelau, P. B. F.; Silva, M. R.; Augusti, R.; Melo, J. O. F.; Fante, C. A.; Quim. Nova 2020, 43, 579.
  • 26
    Silva, V. D. M.; Macedo, M. C. C.; Santos, A. N.; Silva, M. R.; Augusti, R.; Lacerda, I. C. A.; Melo, J. O. F.; Fante, C. A.; Rapid Commun. Mass Spectrom. 2020b, 34, 8883.
  • 27
    Minighin, E. C.; Anastácio, L. R.; Melo, J. O. F.; Labanca, R. A.; Res. Society Develop 2020, 9, e760986116.
  • 28
    e Loyola, A. C. F.; Silva, V. D.; Silva, M. R.; Rodrigues, C. G.; Dos Santos, A. N.; Melo, J. O.; Fante, C. A.; J. Braz. Chem. Soc. 2021, 32, 953.
  • 29
    Price, M. L.; Hagerman, A. E.; J. Agric. Food Chem 1980, 28, 459.
  • 30
    Rodriguez-Amaya D. B.; J. Food Compos. Anal 1996, 196.
  • 31
    Rufino, M. S. M.; Alves, R. E.; Brito, E. S.; Pérez-Jiménez, J.; Saura-Calixto, F.; Filho, J. M.; Food Chem 2010, 121, 996.
  • 32
    Sahan, Y.; Cansev, A.; Gulen, H.; Food Sci. Biotechnol 2013, 22, 613.
  • 33
    AOAC. Association of Official Analytical Chemists. Official methods of analysis of the Association of Official Analytical Chemists, 19th ed., Ed. William Horwitz: Gaithersburg, 2012.
  • 34
    Campelo, F. A.; Henriques, G. S.; Simeone, M. L. F.; Queiroz, V. A. V.; Silva, M. R.; Augusti, R.; Melo, J. O. F.; Lacerda, I. C. A.; Araujo, R. L. B.; J. Braz. Chem. Soc 2020, 31, 788.
  • 35
    Silva, E. B. M.; Augusti, R.; Melo, J. O. F.; Takahashi, J. A.; Araújo, R. L. B.; Quim. Nova 2020, 43, 319.
  • 36
    Haslam, E.; J. Nat. Prod. 1996, 59, 205.
  • 37
    Brandes.; Feitas, E. A. G.; Agropecuária Catarinense 1992, 5, 44.
  • 38
    De Angelis, R. C.; Importância de alimentos vegetais na proteção da saúde: fisiologia da nutrição protetora e preventiva de enfermidades degenerativas, Atheneu: São Paulo, 2001, p. 295.
  • 39
    Sentanin, M. A.; Amaya, D. B. R.; Food Sci. Technol. 2007, 27, 13.
  • 40
    Murillo, E.; Giuffrida, D.; Menchaca, D.; Dugo, P.; Torre, G.; Meléndez-Martinez, A. J.; Mondello, L.; Food Chem 2013, 140, 825.
  • 41
    Gonçalves Silva, R. M.; Figueiredo, P. A.; Peixoto, E. C. T.; De M.; Silva, L. P.; Biosci. J. 2013, 30, 556.
  • 42
    Dos Santos, G. M.; Maia, G. A.; Souza, P. H. M.; Costa, J. M. C.; Figueiredo, R. W.; Prado, G. M.; Arch. Latinoam. Nutr. 2008, 58, 187.
  • 43
    Da Costa, G. M.; Silva, V. R. O.; Louzada, M. H.; Queiroz, I. C.; Ciên. Tecnol. Meio Ambiente 2020, 1, 11.
  • 44
    Socaci, S. A.; Fărcaş, A. C.; Diaconeasa, Z. M.; Dan Vodnar, D. C.; Rusu, B.; Tofană, M.; J. Cereal Sci 2018, 80, 180.
  • 45
    Infante, J.; Selani, M. M.; Toledo, N. M. V.; Silveira-Diniz, M. F.; Alencar, S. M.; Spoto, M. H. F.; Braz. J. Food Nutr. 2013, 24, 87.
  • 46
    Tiveron, A. P.; Tese de Doutorado, Universidade Federal de São Paulo, Brasil, 2010.
  • 47
    Chirinos, R.; Pedresch, R.; Rogez, H.; Larondelle, Y.; Campos, D.; Ind. Crops Prod 2013, 47, 145.
  • 48
    Queiroz, V. A. V.; Moraes, E. M.; Schaffert, R. E.; Moreira, A. V.; Ribeiro, S. M. R.; Martino, H. S. D.; Rev. Bras. Milho Sorgo 2011, 10, 180.
  • 49
    Famacognosia: da planta ao medicamento; Simões, C. M. O., org.; 6th ed., Editora da UFSC e UFRGS: Porto Alegre, 2007
  • 50
    Sala, A.; Recio, M. C.; Giner, R.M.; Manez, S.; Tournier, H.; Schinella, G.; Rios, J. L., J. Pharm. Pharmacol. 2002, 54, 365.
  • 51
    Abu-Reidah, I. M.; Ali-Shtayeh, M. S.; Jamous, R. A.; ArráezRomán, D.; Segura-Carretero, A.; Food Chem 2015, 166, 179.
  • 52
    Abid, M.; Yaich, H.; Cheikhrouhou, S.; Khemakhem, I.; Bouaziz, H. A.; Ayadi, M. A.; J. Food Sci Technol. 2017, 54, 2890.
  • 53
    Wang, J.; Jia, Z.; Zhang, Z.; Wang, Y.; Liu, X.; Wang, L.; Lin, R.; Molecules 2017, 22, 476.
  • 54
    Zhang, L.; Zhu, M. T.; Shi, T.; Guo, C.; Huang, Y. S.; Chen, Y.; Xie, M. Y.; Food Funct 2017, 8, 341.
  • 55
    Lee, J. H.; Johnson, J. V.; Talcott, S. T.; J. Agric. Food Chem 2005, 53, 6003.
  • 56
    Kang, J.; Price, W. E., Ashton, J.; Tapsell, L. C.; Johnson, S.; Food Chem 2016, 211, 215.
  • 57
    Cvetanovic, A.; Svarc-Gaji, J.; Maskovic, P.; Savic, S.; Nikolic, L.; Ind. Crops Prod. 2015, 65, 582.
  • 58
    Tsamo, C. V. P.; Herent, M.; Tomekpe, K.; Emaga, T. H.; Quetin-Leclerq, J.; Rogez, H.; Larondelle, Y.; Andre, C.; Food Chem 2015, 167, 197.
  • 59
    Bystrom, L. M.; Lewis, B. A.; Brown, D. L.; Rodriguez, E.; Obendorf, R. L.; Food Chem 2011, 111, 1017.
  • 60
    Schütz, K.; Kammerer, D.; Carle, R.; Schieber, A.; J. Agric. Food Chem 2004, 52, 4090.
  • 61
    Valls, J.; Millán, S.; Martí, M. P.; Borràs, E.; Arola, L.; J. Chromatogr. A 2009, 1216, 7143.
  • 62
    Simirgiotis, M. J.; Schmeda-Hirschmann, G.; Bórquez, J.; Kennelly, E. J.; Molecules 2013, 18, 1672.
  • 63
    De Brito, E. S.; De Araújo, M. C. P.; Lin, L. Z.; Harnly, J.; Food Chem. 2007, 105, 1112.
  • 64
    Wu, X.; Prior, R. L.; J. Agric. Food Chem 2005, 53, 2589.

Publication Dates

  • Publication in this collection
    08 June 2022
  • Date of issue
    2022

History

  • Received
    12 Sept 2021
  • Accepted
    17 Nov 2021
  • Published
    17 Jan 2022
Sociedade Brasileira de Química Instituto de Química, Universidade Estadual de Campinas (Unicamp), CP6154, 13083-0970 - Campinas - SP - Brazil
E-mail: quimicanova@sbq.org.br