Chromatic analysis for predicting anthocyanin content in fruits and vegetables

VIEIRA, Luciana Marques; MARINHO, Letícia Mafle Guimarães; ROCHA, Juliana de Cássia Gomes; BARROS, Frederico Augusto Ribeiro; STRINGHETA, Paulo César

doi:10.1590/fst.32517

Abstract

The objective of this study was to develop simple mathematical models for the prediction of the total anthocyanin content of fruits and vegetables, using colorimetry. Phenolic extracts of 13 species of fruits and vegetables were produced using 70% acidified ethanol and 70% ethanol. The quantification of the total anthocyanins of the extracts was performed by the spectrophotometric method, and the color characterization was done through the tristimulus colorimeter. The correlation between the L* value and the anthocyanin content was high (r = - 0.95) for extracts produced with 70% ethanol and diluted 20 times. Linear equations based on colorimetric coordinates, with R² from 0.80 to 0.99, were obtained using 70% ethanol and 70% acidified ethanol as extraction solvent, with or without dilutions. Therefore, colorimetry, as a rapid method that does not involve the use of specific solvents, can be used to predict the total anthocyanin content of fruits and vegetables.

Keywords:
anthocyanins; colorimetry; mathematical models; fruits and vegetables

1 Introduction

Anthocyanins are a group of water-soluble blue, purple and red-colored pigments ( Ignat et al., 2011 Ignat, I., Volf, I., & Popa, V. I. (2011). Review A critical review of methods for characterisation of polyphenolic compounds in fruits and vegetables. Food Chemistry, 126(4), 1821-1835. http://dx.doi.org/10.1016/j.foodchem.2010.12.026. PMid:25213963.
http://dx.doi.org/10.1016/j.foodchem.20... ). In the industry, there is a growing interest in these flavonoids due to their potential as a natural colorant and antioxidant capacity. Regular consumption of anthocyanin-containing foods has been associated with the prevention of degenerative ( Ignat et al., 2011 Ignat, I., Volf, I., & Popa, V. I. (2011). Review A critical review of methods for characterisation of polyphenolic compounds in fruits and vegetables. Food Chemistry, 126(4), 1821-1835. http://dx.doi.org/10.1016/j.foodchem.2010.12.026. PMid:25213963.
http://dx.doi.org/10.1016/j.foodchem.20... ), cardiovascular diseases and cancer ( Caridi et al., 2007 Caridi, D., Trenerry, V. C., Rochfort, S., Duong, S., Laugher, D., & Jones, R. (2007). Profiling and quantifying quercetin glucosides in onion (Allium cepa L. ) varieties using capillary zone electrophoresis and high performance liquid chromatography. Food Chemistry, 105(2), 691-699. http://dx.doi.org/10.1016/j.foodchem.2006.12.063.
http://dx.doi.org/10.1016/j.foodchem.20... ).

In plants, anthocyanins play a protective role, protecting them from UV light, pathogens and oxidative damages ( Caridi et al., 2007 Caridi, D., Trenerry, V. C., Rochfort, S., Duong, S., Laugher, D., & Jones, R. (2007). Profiling and quantifying quercetin glucosides in onion (Allium cepa L. ) varieties using capillary zone electrophoresis and high performance liquid chromatography. Food Chemistry, 105(2), 691-699. http://dx.doi.org/10.1016/j.foodchem.2006.12.063.
http://dx.doi.org/10.1016/j.foodchem.20... ). They may be present in all tissues of the plant, including leaves, stems, roots, flowers and fruits and accumulate gradually during development. The anthocyanins content varies widely depending on the species, variety, environmental factors and growth, and storage conditions ( Caridi et al., 2007 Caridi, D., Trenerry, V. C., Rochfort, S., Duong, S., Laugher, D., & Jones, R. (2007). Profiling and quantifying quercetin glucosides in onion (Allium cepa L. ) varieties using capillary zone electrophoresis and high performance liquid chromatography. Food Chemistry, 105(2), 691-699. http://dx.doi.org/10.1016/j.foodchem.2006.12.063.
http://dx.doi.org/10.1016/j.foodchem.20... ). The maximum content is observed at harvest time and, during senescence, there is a reduction of this pigment ( Chen et al., 2015 Chen, S., Zhang, F., Ning, J., Liu, X., Zhang, Z., & Yang, S. (2015). Predicting the anthocyanin content of wine grapes by NIR hyperspectral imaging. Food Chemistry, 172, 788-793. http://dx.doi.org/10.1016/j.foodchem.2014.09.119. PMid:25442621.
http://dx.doi.org/10.1016/j.foodchem.20... ).

The quantification of anthocyanins may be interesting for determining the harvesting point of the vegetables ( Chen et al., 2015 Chen, S., Zhang, F., Ning, J., Liu, X., Zhang, Z., & Yang, S. (2015). Predicting the anthocyanin content of wine grapes by NIR hyperspectral imaging. Food Chemistry, 172, 788-793. http://dx.doi.org/10.1016/j.foodchem.2014.09.119. PMid:25442621.
http://dx.doi.org/10.1016/j.foodchem.20... ) as well as for industries and rural producers to evaluate the quality of fresh and processed products ( Poiana et al., 2012 Poiana, M. A., Alexa, E., & Mateescu, C. (2012). Tracking antioxidant properties and color changes in low-sugar bilberry jam as effect of processing, storage and pectin concentration. Chemistry Central Journal, 6(4), 2-11. http://dx.doi.org/10.1186/1752-153X-6-4. PMid:22248151.
http://dx.doi.org/10.1186/1752-153X-6-4... ), since their quality is directly related to the content of this pigment and other phenolic compounds present. A number of techniques can be used to determine the anthocyanin content of plants, including UV-visible spectrophotometry ( Lees & Francis, 1972 Lees, D., & Francis, F. (1972). Standardization of pigment analyses in cranberries. HortScience, 7, 83-84. ), mass spectrometry ( Vera de Rosso et al., 2008 Vera de Rosso, V., Hillebrand, S., Cuevas Montilla, E., Bobbio, F. O., Winterhalter, P., & Mercadante, A. Z. (2008). Determination of anthocyanins from acerola (Malpighia emarginata DC.) and açaí (Euterpe oleracea Mart. ) by HPLC-PDA-MS/MS. Journal of Food Composition and Analysis, 21(4), 291-299. http://dx.doi.org/10.1016/j.jfca.2008.01.001.
http://dx.doi.org/10.1016/j.jfca.2008.0... ) and nuclear magnetic resonance (NMR) ( Ella Missang et al., 2003 Ella Missang, C., Guyot, S., & Renard, C. M. (2003). Flavonols and Anthocyanins of Bush Butter, Dacryodes edulis (G. Don) H.J. Lam, Fruit. Changes in Their Composition during Ripening. Journal of Agricultural and Food Chemistry, 51(25), 7475-7480. http://dx.doi.org/10.1021/jf0346399. PMid:14640602.
http://dx.doi.org/10.1021/jf0346399 ... ). However, some of these techniques require high preparation time, high cost and specialized reagents. The biological properties of anthocyanins and their health benefits are increasingly intensifying efforts to discover and optimize methods of extraction, quantification and identification in natural sources using comprehensive and rapid methods ( Ignat et al., 2011 Ignat, I., Volf, I., & Popa, V. I. (2011). Review A critical review of methods for characterisation of polyphenolic compounds in fruits and vegetables. Food Chemistry, 126(4), 1821-1835. http://dx.doi.org/10.1016/j.foodchem.2010.12.026. PMid:25213963.
http://dx.doi.org/10.1016/j.foodchem.20... ; Pappas et al., 2011 Pappas, C. S., Takidelli, C., Tsantili, E., Tarantilis, P. A., & Polissiou, M. G. (2011). Quantitative determination of anthocyanins in three sweet cherry varieties using diffuse reflectance infrared Fourier transform spectroscopy. Journal of Food Composition and Analysis, 24(1), 17-21. http://dx.doi.org/10.1016/j.jfca.2010.07.001.
http://dx.doi.org/10.1016/j.jfca.2010.0... ).

The use of colorimeters has been considered an important tool for the quantification of anthocyanins ( Heredia et al., 1998 Heredia, F. J., Francia-Aricha, E. M., Rivas-Gonzalo, J. C., Vicario, I. M., & Santos-Buelga, C. (1998). Chromatic characterization of anthocyanins from red grapes - I. pH effect. Food Chemistry, 63(4), 491-498. http://dx.doi.org/10.1016/S0308-8146(98)00051-X.
http://dx.doi.org/10.1016/S0308-8146(98... ). The color measurement can be used as an indirect way of analyzing the colored components of a food product, since it is simpler and faster compared to the chemical analyses ( Alves et al., 2008 Alves, C. C. O., Resende, J. V., Cruviel, R. S. R., & Prado, M. E. T. (2008). Estabilidade da microestrutura e do teor de carotenóides de pós obtidos da polpa de pequi (Caryocar brasiliense Camb.) liofilizada. Ciência e Tecnologia de Alimentos, 28(4), 830-839. ). Some studies demonstrate a correlation between the color measurements of the CIELAB system, which determine a three-dimensional color space and represent the color stimulus as an achromatic signal (L*) and two chromatic channels representing blue-yellow (b*) and red-green (a*), and the presence of bioactive compounds such as carotenoids, anthocyanins and other phenolics, betalaine and chlorophyll in plants ( Sant’Anna et al., 2013 Sant’Anna, V., Gurak, P. D., Marczak, L. D. F., & Tessaro, I. C. (2013). Tracking bioactive compounds with colour changes in foods - A review. Food Chemistry , 98, 601-608. http://dx.doi.org/10.1016/j.foodchem.2013.09.106.
https://doi.org/10.1016/j.foodchem.2013.... ).

Studies involving the correlation of the anthocyanin content with the color of some fruits and anthocyanin content prediction using an infrared spectroscopy model system ( Pappas et al., 2011 Pappas, C. S., Takidelli, C., Tsantili, E., Tarantilis, P. A., & Polissiou, M. G. (2011). Quantitative determination of anthocyanins in three sweet cherry varieties using diffuse reflectance infrared Fourier transform spectroscopy. Journal of Food Composition and Analysis, 24(1), 17-21. http://dx.doi.org/10.1016/j.jfca.2010.07.001.
http://dx.doi.org/10.1016/j.jfca.2010.0... ; Chen et al., 2015 Chen, S., Zhang, F., Ning, J., Liu, X., Zhang, Z., & Yang, S. (2015). Predicting the anthocyanin content of wine grapes by NIR hyperspectral imaging. Food Chemistry, 172, 788-793. http://dx.doi.org/10.1016/j.foodchem.2014.09.119. PMid:25442621.
http://dx.doi.org/10.1016/j.foodchem.20... ; Montes et al., 2005 Montes, C., Vicario, I. M., Raymundo, M., Fett, R., & Heredia, F. J. (2005). Application of tristimulus colorimetry to optimize the extraction of anthocyanins from Jaboticaba (Myricia Jaboticaba Berg.). Food Research International, 38(8–9), 983-988. http://dx.doi.org/10.1016/j.foodres.2005.01.016.
http://dx.doi.org/10.1016/j.foodres.200... ), have already been done, however, studies related to the prediction of the anthocyanin content in fruits and vegetables using colorimetry were not found. Thus, the objective of this work was to develop prediction models for anthocyanin content of 13 fresh fruits and vegetables using L*, a*, b*, C* and h* values of the colorimeter.

2 Material and Methods

2.1 Fruits and vegetables used in the study

Samples of jabuticaba (Myrciaria jaboticaba), camu-camu ( Myrciaria dubia), plum (Prunus salicina), raspberry ( Rubus idaeus), strawberry (Fragaria sp,), red pitaya ( Hylocereus undatus), jussara (Euterpe edulis), blueberry (Vaccinium myrtillus), blackberry (Morus nigra ), red globe grape (Vitis vinífera), eggplant (Solanum melongena) and purple cabbage (Brassica oleracea) were obtained from the Viçosa, Minas Gerais, Brazil, retailer from January to June 2016. Açaí fruits (Euterpe oleracea) were obtained in Belém, Pará, Brazil. After collection, the fruits were immediately evaluated, except the açaí fruit, which was frozen and transported by air to the analysis laboratory.

2.2 Phenolic extraction and total anthocyanins determination

Phenolic extracts (extracts rich in phenolic compounds) were obtained from: skins of the plum, eggplant, grape and jabuticaba; pulp of the red pitaya; purple cabbage leaves; and whole fruits of the blackberry, camu camu, raspberry, blueberry, strawberry, açai and jussara.

The phenolic extract of each fruit or vegetable was obtained from 5 g of the ground material with 50 mL of solvent. In the case of jussara and açai, 25 g of the whole fruit was macerated with 50 mL of solvent. Two solvents were used: 70% ethanol solution with 1.5 mol·L ^-1 HCl (85:15, v/v) and 70% ethanol. The suspension was allowed to stand in the absence of light and under refrigeration (7 ± 1 °C) for 24 hours. After 24 hours, the samples were filtered on Whatman N^o. 1 paper under vacuum in a Buchner funnel and the volume was completed to 50 mL.

The quantification of total anthocyanins in the phenolic extracts was done using a SHIMADZU spectrophotometer (UV-1601PC, Kyoto, Japan), according to the method proposed by ( Lees & Francis, 1972 Lees, D., & Francis, F. (1972). Standardization of pigment analyses in cranberries. HortScience, 7, 83-84. ). The extracts were subjected to a reading in a spectrophotometer at 535 nm and the total anthocyanin content was obtained using the Equation 1 $C ’ = (A x F D) / (ε x b)$ , where C’: total anthocyanin content (mg. L^-1); A: absorbance (535 nm); ℇ: absorbance coefficient of cyanidines (98.2); b: thickness of the cuvette (1 cm); FD: dilution factor of the extract. The total anthocyanin content was expressed in mg.100 mL^-1 of extract.

For each evaluated species 5 replicates were made and, for each replicate, approximately 100 g of the material was ground. The analyses were performed in duplicate.

2.3 Colorimetric characterization of the phenolic extracts

The color characterization of each phenolic extract, obtained with 70% acidified ethanol and 70% ethanol, was performed in a ColorQuest XE colorimeter (Spera, Hunter Lab, Reston) under D65 illuminant and Hunterlab's Universe software. L* (luminosity), a* (intensity of red and green) and b* (intensity of yellow and blue) were read by reflectance. The hue (h*) value was calculated using the Equation 2 $h * = a r c t a n (b * / a *)$ and the saturation (C*) value was calculated using the Equation 3 C* = $\sqrt{a^{* 2} + b^{* 2}}$ from the values of a* and b*.

2.4 Correlations between anthocyanin content and colorimetric coordinates

Phenolic extracts from the 13 species of fruits and vegetables obtained with the two extraction solvents (70% acidified ethanol and 70% ethanol) were used. Phenolic extracts were diluted 2, 5, 10 and 20 times. The L*, a* and b* values of the colorimetric measurement and the C* and h* values were obtained for all phenolic extracts.

The correlation between the L*, a*, b*, C* and h* values and the total anthocyanin content was determined by the Pearson correlation (r). To find r value, it was assessed for each solvent (70% acidified ethanol and 70% ethanol) and for each dilution (2, 5, 10 and 20 times), all 5 replicates, or, in other words, 65 phenolic extracts obtained from the 13 fruits and vegetables.

2.5 Development of prediction models

Linear regression models were found according to Equation 4:

Y = β o + β_{1} X_{1} + β_{2} X_{2} + β_{3} X_{3} + β_{4} X_{4} + β_{5} X_{5}

(4)

Where: being Y the response function of the experimental data for the total anthocyanin content; $X_{1}, X_{2}, X_{3}, X_{4} e X_{5}$ are independent variables corresponding to L*, a*, b*, C* and h* colorimetric coordinates respectively, and β are the estimated coefficients adjusted to the anthocyanin content of the phenolic extracts obtained with 70% acidified ethanol and 70% ethanol, diluted 2, 5, 10 and 20 times, with the colorimetric coordinates. In order to obtain the models, mean values of total anthocyanins and colorimetric parameters of 65 phenolic extracts obtained from the 13 fruits and vegetables were used.

2.6 Statistical Analysis

The mean content of total anthocyanins for the two extraction solvents was compared using the F test, p <0.05. Correlations between L*, a* and b* coordinates of the colorimetric measurement and C* and h* parameters with the total anthocyanin content, determined by the Pearson correlation (r), and the multiple linear regression models used to predict the content of anthocyanins were obtained by the Stepwise method using the IBM SPSS software (V. 21.0, IBM Corp. Released 2012).

3 Results and discussion

3.1 Total anthocyanin content

Total anthocyanin content in the phenolic extracts varied from 0.22 to 365.86 mg·100 mL^-1 of extract in the 13 studied fruits and vegetables, and as such, they are considered good sources of this pigment ( Table 1 ). There was also a significant variation between the content of anthocyanins in the phenolic extracts as a function of the extracting solvent used. However, for açaí, jussara and blueberry fruits, no significant variation was observed between the two solvents used for pigment extraction, suggesting that pH reduction is not always necessary in the production of anthocyanin extracts. The extraction of anthocyanins from açaí, jussara and blueberry can be done without the use of acids, reducing the risk to the manipulator and the contamination of the environment.

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Table 1
Minimum, maximum and average total anthocyanins content, among the five replications, in the phenolic extracts of the fruits and vegetables studied, for two extraction solvents.

Solvent acidification increased anthocyanins extraction efficiency for some fruits and vegetables. The increase in anthocyanin content was 1.2, 1.6, 5.8 and 30 times for raspberry, plum, eggplant and purple cabbage ( Table 1 ), respectively, suggesting that denaturation of cell membranes, either by physical or chemical constitution, is difficult in these species, or that the anthocyanins are more strongly adhered to the vacuoles of the cells. In the case of purple cabbage, this large increase in the extraction with the acidification of the extraction solvent has already been demonstrated by Chandrasekhar et al. (2012) Chandrasekhar, J., Madhusudhan, M. C., & Raghavarao, K. S. M. S. (2012). Extraction of anthocyanins from red cabbage and purification using adsorption. Food and Bioproducts Processing, 90(4), 615-623. http://dx.doi.org/10.1016/j.fbp.2012.07.004.
http://dx.doi.org/10.1016/j.fbp.2012.07... . Moreover, the stability of the anthocyanins increases with the decrease of the pH of the medium.

Acidification of the extraction solvent at pH 2 was not efficient for the release of a greater content of anthocyanins from the vacuoles of the cells of açaí, jussara, blueberry, blackberry, camu-camu, red pitaya, strawberry, Red Globe grapes and jabuticaba. For the last six, the content of anthocyanins in the phenolic extract was lower when using acidified ethanol. Acidification may be necessary to promote denaturation of cell membranes with subsequent release of anthocyanins present in the vacuole of some plant species ( Rodriguez-Saona & Wrolstad, 2001 Rodriguez-Saona, L.E, & Wrolstad, R. (2001). Extraction, isolation and purification of anthocyanins. Current Protocols in Food Analytical Chemistra, 1(1) 1-11. ), however, it is necessary to know the behavior of different species for an efficient extraction. It has been reported that the extraction of acylated anthocyanins under acidic conditions may cause their total or partial hydrolysis ( Revilla et al., 1998 Revilla, E., Ryan, J.-M., & Martín-Ortega, G. (1998). Comparison of several procedures used for the extraction of anthocyanins from red grapes. Journal of Agricultural and Food Chemistry, 46(11), 4592-4597. http://dx.doi.org/10.1021/jf9804692.
http://dx.doi.org/10.1021/jf9804692 ... ) and the extraction efficiency may be related to the type of acid used ( Montes et al., 2005 Montes, C., Vicario, I. M., Raymundo, M., Fett, R., & Heredia, F. J. (2005). Application of tristimulus colorimetry to optimize the extraction of anthocyanins from Jaboticaba (Myricia Jaboticaba Berg.). Food Research International, 38(8–9), 983-988. http://dx.doi.org/10.1016/j.foodres.2005.01.016.
http://dx.doi.org/10.1016/j.foodres.200... ). Pompeu et al. (2009) Pompeu, D. R., Silva, E. M., & Rogez, H. (2009). Optimisation of the solvent extraction of phenolic antioxidants from fruits of Euterpe oleracea using Response Surface Methodology. Bioresource Technology, 100(23), 6076-6082. http://dx.doi.org/10.1016/j.biortech.2009.03.083. PMid:19581082.
http://dx.doi.org/10.1016/j.biortech.20... have shown that the use of 70-80% (v/v) ethanol as the extracting solvent containing 0.065 and 0.074 mol·L^-1 of hydrochloric acid increases the extraction efficiency of the total phenolics and total anthocyanins of açaí fruit. However, in our work, there was no effect of acidification of the solvent (70% ethanol) with hydrochloric acid at pH 2.0 in the extraction of anthocyanins from these fruits.

Fruits and vegetables can be divided into three large groups according to the aglycone bound to the C15 skeleton of the anthocyanin molecule: pelargonidin, cyanidin/peonidine and a group of multiple anthocyanins. All anthocyanins are soluble in polar solvents, and the use of water added to the solvent facilitates the extraction of more hydrophilic anthocyanins ( Fuleki & Francis, 1968 Fuleki, T., & Francis, F. (1968). Quantitative methods for anthocyanins. 1. Extraction and determination of total anthocyanin in cranberries. Journal of Food Science , 33(1), 72-77. http://dx.doi.org/10.1111/j.1365-2621.1968.tb00887.x.
http://dx.doi.org/10.1111/j.1365-2621.1... ). Additionally, the use of water as extracting solvent for anthocyanins may be efficient for some species that contain a large amount of water in their constitution, such as cherries ( Grigoras et al., 2012 Grigoras, C. G., Destandau, E., Zubrzycki, S., & Elfakir, C. (2012). Sweet cherries anthocyanins: An environmental friendly extraction and purification method. Separation and Purification Technology, 100, 51-58. http://dx.doi.org/10.1016/j.seppur.2012.08.032.
http://dx.doi.org/10.1016/j.seppur.2012... ). On the other hand, the use of acidified solvents to extract anthocyanins can produce proanthocyanidins and flavanols, which may result in an overestimation of the total anthocyanins, as discussed in the study done by Revilla et al. (1998) Revilla, E., Ryan, J.-M., & Martín-Ortega, G. (1998). Comparison of several procedures used for the extraction of anthocyanins from red grapes. Journal of Agricultural and Food Chemistry, 46(11), 4592-4597. http://dx.doi.org/10.1021/jf9804692.
http://dx.doi.org/10.1021/jf9804692 ... . Despite these drawbacks, many authors continue to use extraction with solvents containing hydrochloric acid to extract anthocyanins from a variety of sources ( Montes et al., 2005 Montes, C., Vicario, I. M., Raymundo, M., Fett, R., & Heredia, F. J. (2005). Application of tristimulus colorimetry to optimize the extraction of anthocyanins from Jaboticaba (Myricia Jaboticaba Berg.). Food Research International, 38(8–9), 983-988. http://dx.doi.org/10.1016/j.foodres.2005.01.016.
http://dx.doi.org/10.1016/j.foodres.200... ; Fan et al., 2008 Fan, G., Han, Y., Gu, Z., & Chen, D. (2008). Optimizing conditions for anthocyanins extraction from purple sweet potato using response surface methodology (RSM). Lebensmittel-Wissenschaft + Technologie, 41(1), 155-160. http://dx.doi.org/10.1016/j.lwt.2007.01.019.
http://dx.doi.org/10.1016/j.lwt.2007.01... ; Teixeira et al., 2008 Teixeira, N., Stringheta, P. C., & Oliveira, A. (2008). Comparação de métodos para quantificação de antocianinas. Revista Ceres , 55(4), 297-304. ; Zanatta et al., 2005 Zanatta, C. F., Cuevas, E., Bobbio, F. O., Winterhalter, P., & Mercadante, A. Z. (2005). Determination of anthocyanins from Camu-camu (Myrciaria dubia) by HPLC-PDA, HPLC-MS, and NMR. Journal of Agricultural and Food Chemistry, 53(24), 9531-9535. http://dx.doi.org/10.1021/jf051357v. PMid:16302773.
http://dx.doi.org/10.1021/jf051357v ... ; Dai et al., 2009 Dai, J., Gupte, A., Gates, L., & Mumper, R. J. (2009). A comprehensive study of anthocyanin-containing extracts from selected blackberry cultivars: Extraction methods, stability, anticancer properties and mechanisms. Food and Chemical Toxicology, 47(4), 837-847. http://dx.doi.org/10.1016/j.fct.2009.01.016. PMid:19271318.
http://dx.doi.org/10.1016/j.fct.2009.01... ; Patil et al., 2009 Patil, G., Madhusudhan, M. C., Ravindra Babu, B., & Raghavarao, K. S. M. S. (2009). Extraction, dealcoholization and concentration of anthocyanin from red radish. Chemical Engineering and Processing: Process Intensification, 48(1), 364-369. http://dx.doi.org/10.1016/j.cep.2008.05.006.
http://dx.doi.org/10.1016/j.cep.2008.05... ; Pompeu et al., 2009 Pompeu, D. R., Silva, E. M., & Rogez, H. (2009). Optimisation of the solvent extraction of phenolic antioxidants from fruits of Euterpe oleracea using Response Surface Methodology. Bioresource Technology, 100(23), 6076-6082. http://dx.doi.org/10.1016/j.biortech.2009.03.083. PMid:19581082.
http://dx.doi.org/10.1016/j.biortech.20... ).

Thus, based on the literature and results of this study, the acidification of the extraction solvent is not always necessary to increase extraction efficiency of anthocyanins, however, the acidification is important in order to improve the stability of anthocyanins from fruits and vegetables.

3.2 Colorimetric characterization of the phenolic extracts

The colorimetric parameters (L*, a*, b*, C and h*) allowed the characterization of the color of each phenolic extract, without dilutions. The values of L* ranged from 44.53 (strawberry) to 25.56 (jussara), and from 25.01 (açaí) to 57.96 (purple cabbage) in extracts produced with acidified ethanol and 70% ethanol, respectively. In general, higher L* values, a parameter related to light transmission, were obtained for the phenolic extracts produced with 70% ethanol, compared to the extracts produced with acidified ethanol (darker extracts) ( Table 2 ). The lowest L* values (darkest extracts) were observed for phenolic extracts obtained from açaí and jussara fruits ( Table 2 ). The L* coordinate represents how light or dark the sample presents itself, with values ranging from 0 (totally black) to 100 (totally white). The increase of the L* value with the increase of the pH can be related to the change in the form of the anthocyanins present in the phenolic extracts ( Heredia et al., 1998 Heredia, F. J., Francia-Aricha, E. M., Rivas-Gonzalo, J. C., Vicario, I. M., & Santos-Buelga, C. (1998). Chromatic characterization of anthocyanins from red grapes - I. pH effect. Food Chemistry, 63(4), 491-498. http://dx.doi.org/10.1016/S0308-8146(98)00051-X.
http://dx.doi.org/10.1016/S0308-8146(98... ; Montes et al., 2005 Montes, C., Vicario, I. M., Raymundo, M., Fett, R., & Heredia, F. J. (2005). Application of tristimulus colorimetry to optimize the extraction of anthocyanins from Jaboticaba (Myricia Jaboticaba Berg.). Food Research International, 38(8–9), 983-988. http://dx.doi.org/10.1016/j.foodres.2005.01.016.
http://dx.doi.org/10.1016/j.foodres.200... ).

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Table 2
Mean colorimetric coordinates of the phenolic extracts from fruits and vegetables, obtained with two extraction solvents (70% acidified ethanol and 70% ethanol), without dilutions.

The high L* value obtained with the strawberry phenolic extract, for both solvents, confirmed the low concentration of anthocyanins in the extracts. In the case of purple cabbage, lower L* values were obtained with the phenolic extracts produced with acidified solvent compared to 70% ethanol, suggesting a darker extract (i.e. more concentrated). This result confirms the higher efficiency of acidified ethanol extraction for purple cabbage, confirming the higher content of anthocyanins measured in the extract, as already observed in Table 1 .

The a* coordinate can assume values from -80 (green) to +100 (red) ( Alves et al., 2008 Alves, C. C. O., Resende, J. V., Cruviel, R. S. R., & Prado, M. E. T. (2008). Estabilidade da microestrutura e do teor de carotenóides de pós obtidos da polpa de pequi (Caryocar brasiliense Camb.) liofilizada. Ciência e Tecnologia de Alimentos, 28(4), 830-839. ). In this study, higher a* values (+0.25 to +39.54) were obtained in extracts produced with 70% acidified ethanol. The a* values for the jussara phenolic extracts were the lowest observed for both solvents. This fact can be explained by the high concentration of anthocyanins in the jussara fruit phenolic extract (Table 1).

Numerous processes, including pH, may affect the color and stability of anthocyanins potentially leading to changes in the nutraceutical properties of bioactive compounds ( Sant’Anna et al., 2013 Sant’Anna, V., Gurak, P. D., Marczak, L. D. F., & Tessaro, I. C. (2013). Tracking bioactive compounds with colour changes in foods - A review. Food Chemistry , 98, 601-608. http://dx.doi.org/10.1016/j.foodchem.2013.09.106.
https://doi.org/10.1016/j.foodchem.2013.... ). These pigments are subject to chemical transformations in aqueous medium in the fundamental state. In an acidic medium, anthocyanins are in the form of ozone salts with a bright-red color. As the pH increases to neutral, they tend to have a quinoidal structure with a purple coloration and in alkaline medium, their hue changes to blue ( Giusti & Wrolstad, 2001 Giusti, M. M., & Wrolstad, R. E. (2001). Characterization and measurement of anthocyanins by UV‐visible spectroscopy. In R. E. Wrolstad & S. J. Schwartz (Eds.), Current protocols in food analytical chemistry (Chap.1; pp. F1.2.1-F1.2.13). New York: John Wiley & Sons, Inc. http://dx.doi.org/10.1002/0471142913.faf0102s00
http://dx.doi.org/10.1002/0471142913.fa... ), suggesting that the change in the structure of the anthocyanins and the color change of the product can be measured by colorimetric techniques ( Sant’Anna et al., 2013 Sant’Anna, V., Gurak, P. D., Marczak, L. D. F., & Tessaro, I. C. (2013). Tracking bioactive compounds with colour changes in foods - A review. Food Chemistry , 98, 601-608. http://dx.doi.org/10.1016/j.foodchem.2013.09.106.
https://doi.org/10.1016/j.foodchem.2013.... ).

The effect of pH on the color of anthocyanins was visually observed with purple cabbage (data not shown). The phenolic extracts of this vegetable when acidified showed intense red color and, when not acidified, they tended to purple. This observation confirms the data obtained for the a* coordinate of the colorimetric measurement when comparing the two extraction solvents, since the a* value obtained in the phenolic extracts produced with acidified ethanol was 5 times higher than the a* value produced without acidification.

The b* coordinate can range from -50 (blue) to +70 (yellow) ( Alves et al., 2008 Alves, C. C. O., Resende, J. V., Cruviel, R. S. R., & Prado, M. E. T. (2008). Estabilidade da microestrutura e do teor de carotenóides de pós obtidos da polpa de pequi (Caryocar brasiliense Camb.) liofilizada. Ciência e Tecnologia de Alimentos, 28(4), 830-839. ). In this study, b* values varied from -5.48 to 26.42 (for 70% acidified ethanol) and from -1.41 to 26.97 (for 70% ethanol) ( Table 2 ). Comparing the two extraction solvents for the same studied vegetable, phenolic extracts produced with 70% acidified ethanol showed, in general, higher b* values, indicating a greater tendency of the extracts to yellow coloration in detriment to the blue coloration.

The hue (h*) characterizes the color quality, allowing it to be differentiated, varies from 0 to 360º. In the phenolic extracts produced with 70% ethanol, the h* value ranged from 24.73 (jussara) to 77.80 (açaí); While in their acidified phenolic extracts, the h* value ranged from 7.67 (jussara) to 85.79 (strawberry) ( Table 2 ). The h* value for the phenolic extracts, regardless of the solvent, ranged from 0 to 90º, confirming their red to yellowish-red coloration.

Chroma (C*) or color saturation indicates whether the colors of the phenolic extracts are stronger or lighter depending on the solvent. Greater differences in C* values were observed for the phenolic extracts of strawberry and purple cabbage when compared to the two extraction solvents. In the case of purple cabbage, the C* values confirm the visual observation that phenolic extracts produced with 70% ethanol were darker (tending to purple) and phenolic extracts produced with acidified ethanol were lighter (tending to red). This difference was also observed for the anthocyanin content in the extracts, since the content increased from 0.22 mg / 100 mL to 6.54 mg / 100 mL when the acidification of the solvent was performed. For the strawberry, phenolic extracts obtained with ethanol 70% showed a C* value of 3.5 times smaller than that obtained with acidified ethanol. This result suggests a possible correlation between C* and anthocyanin content of the phenolic extracts obtained from the 13 species studied. The reduction of C* value with the increase of pH (from 1.5 to 5), was observed in phenolic extracts of grape skins ( Heredia et al., 1998 Heredia, F. J., Francia-Aricha, E. M., Rivas-Gonzalo, J. C., Vicario, I. M., & Santos-Buelga, C. (1998). Chromatic characterization of anthocyanins from red grapes - I. pH effect. Food Chemistry, 63(4), 491-498. http://dx.doi.org/10.1016/S0308-8146(98)00051-X.
http://dx.doi.org/10.1016/S0308-8146(98... ). The increase of pH led to the reduction of C* values of phenolic extracts obtained from Chinese bayberry (Myrica rubra) ( Bao et al., 2005 Bao, J., Cai, Y., Sun, M., Wang, G., & Corke, H. (2005). Anthocyanins, flavonols, and free radical scavenging activity of Chinese Bayberry (Myrica rubra) extracts and their color properties and stability. Journal of Agricultural and Food Chemistry , 53(6), 2327-2332. http://dx.doi.org/10.1021/jf048312z. PMid:15769176.
http://dx.doi.org/10.1021/jf048312z ... ).

Differences between C* and h* with solvent acidification were found, suggesting qualitative and quantitative differences between the anthocyanins present in the phenolic extracts. The C* value is the quantitative component of chromaticity, and the hue (h*) value, the qualitative. Quantitative differences in the phenolic extract of jabuticaba changing the extraction solvent were observed by Montes et al. (2005) Montes, C., Vicario, I. M., Raymundo, M., Fett, R., & Heredia, F. J. (2005). Application of tristimulus colorimetry to optimize the extraction of anthocyanins from Jaboticaba (Myricia Jaboticaba Berg.). Food Research International, 38(8–9), 983-988. http://dx.doi.org/10.1016/j.foodres.2005.01.016.
http://dx.doi.org/10.1016/j.foodres.200... .

3.3 Correlations between total anthocyanin content and colorimetric coordinates

High correlations between the color measurements L*, a*, b*, C* and h*, and the total anthocyanin content in the phenolic extracts (with and without dilutions) obtained from 13 fruits and vegetables were observed Table 3 . L* values were higher as dilution increased (2, 5, 10 and 20 times). A low variation in the a* value was observed among the phenolic extracts, diluted or not, with 70% acidified ethanol. In general, b* values were higher in the phenolic extract without dilution, and reduced as the dilutions increased, indicating a tendency to the blue color.

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Table 3
Colorimetric coordinates (Mean of 13 samples ± standard deviation) and Pearson Correlation (r) between the L* (r₁), a* (r₂), b* (r₃ ), C* (r₄) and h* (r₅) coordinates, and the total anthocyanin content of 13 fruits and vegetables for both extraction solvents (70% acidified ethanol and 70% ethanol) and the dilutions (2, 5, 10 and 20 times).

The anthocyanins content is strongly correlated, r above 0.9, to the L* coordinate for phenolic extracts produced with 70% ethanol and diluted 20 times ( Table 3 ). According to Sant’Anna et al. (2013) Sant’Anna, V., Gurak, P. D., Marczak, L. D. F., & Tessaro, I. C. (2013). Tracking bioactive compounds with colour changes in foods - A review. Food Chemistry , 98, 601-608. http://dx.doi.org/10.1016/j.foodchem.2013.09.106.
https://doi.org/10.1016/j.foodchem.2013.... , the change in L* values is a good indicator of the alteration in the polyphenol content.

It is known that methods with high correlation can be used interchangeably, without affecting the interpretation of the results, because they bring similar information. This high correlation between the total anthocyanin content and the L* coordinate indicates that colorimetry can be an important tool for the prediction of the anthocyanin content of fruits and vegetables.

The negative r value found for L* correlation and the total anthocyanin content indicates that high L* values are related to low anthocyanin values, thus, low L* values are desirable because they are related to more efficient anthocyanin extractions. A high correlation between the colorimetric coordinate L* and the anthocyanin content has been reported in literature by Montes et al. (2005) Montes, C., Vicario, I. M., Raymundo, M., Fett, R., & Heredia, F. J. (2005). Application of tristimulus colorimetry to optimize the extraction of anthocyanins from Jaboticaba (Myricia Jaboticaba Berg.). Food Research International, 38(8–9), 983-988. http://dx.doi.org/10.1016/j.foodres.2005.01.016.
http://dx.doi.org/10.1016/j.foodres.200... in a study with jabuticaba. The coordinates a* and b* correlate well with the anthocyanin content of the 13 fruits and vegetables in extracts with 70% acidified ethanol, diluted or not, compared to non-acidified extract; however, the coordinate a* did not correlate well with the anthocyanin content in phenolic extracts produced with 70% acidified ethanol and diluted 20 times ( Table 3 ).

The C* and h* values showed a correlation (r) greater than 0.6 with the total anthocyanin content of some phenolic extracts, mainly with acidified 70% ethanol ( Table 3 ). Phenolic extracts produced with 70% acidified ethanol, without dilution, presented a negative correlation (r) of 0.85 with the h* value ( Table 3 ); this negative correlation indicates that h* value increases when the total anthocyanin content is reduced, which was also demonstrated by Sant’Anna et al. (2013) Sant’Anna, V., Gurak, P. D., Marczak, L. D. F., & Tessaro, I. C. (2013). Tracking bioactive compounds with colour changes in foods - A review. Food Chemistry , 98, 601-608. http://dx.doi.org/10.1016/j.foodchem.2013.09.106.
https://doi.org/10.1016/j.foodchem.2013.... . It also indicates that the pigment is associated with the red intensity of the phenolic extract produced.

3.4 Development of prediction models based on colorimetric coordinates

Simple mathematical models with high values of R² were obtained in this study, where 13 fruits and vegetables containing different total anthocyanins contents were used ( Table 4 ). For phenolic extracts produced with acidified 70% ethanol, the adjusted equation with the highest r² value ( $y = 474.31 - 5.89 h * - 10.824 C * + 9.586 a *, R^{2} = 0.99$ ) was obtained for the phenolic extract without dilution ( Table 4 ). Using the L* and a* or L* and C* values, it was possible to predict the anthocyanin content in the phenolic extracts diluted 10 and 20 times, using equations with R² greater than 0.80 ( Table 4 ). No equations with high R² were obtained for the phenolic extracts diluted 2 and 5 times.

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Table 4
Adjusted multiple regression equations to determine the total anthocyanin contents of 13 fruits and vegetables using colorimetric coordinates (L*, a*, b*, C* and h*).

It was possible to adjust at least one linear regression to predict total anthocyanin content of the phenolic extracts produced with 70% ethanol without acidification and diluted 5, 10 and 20 times using different colorimetric coordinates. The equation with the highest R ² value ( $y = 47.986 - 0.675 L * - 0.367 a * - 0.315 b * - 0.138, R^{2} = 0.99$ ) was obtained for the phenolic extract diluted 10 times ( Table 4 ). The equation obtained for the phenolic extract without dilution was $y = 312.33 - 3.984 h * - 6.751 b * + 5.556 a * - 4.146 C *, R^{2} = 0.98$ .

Knowledge of the content of bioactive compounds, such as anthocyanins, from natural sources has become very important in the preparation of food supplements or nutraceuticals, functional foods, additives and in the pharmaceutical and cosmetic industries. It is known that the anthocyanin content is maximum when grapes, used in the manufacture of wine, are maturing, which is the ideal harvest season. This fact indicates the importance of predicting the total anthocyanin content of grapes during ripening through fast and less tedious methods ( Chen et al., 2015 Chen, S., Zhang, F., Ning, J., Liu, X., Zhang, Z., & Yang, S. (2015). Predicting the anthocyanin content of wine grapes by NIR hyperspectral imaging. Food Chemistry, 172, 788-793. http://dx.doi.org/10.1016/j.foodchem.2014.09.119. PMid:25442621.
http://dx.doi.org/10.1016/j.foodchem.20... ).

It was possible to predict, using colorimetric coordinates of the phenolic extracts obtained from different fruits and vegetables, the anthocyanin content very close to the actual value ( Figure 1 ) using linear equations with higher R² for each dilution and extraction solvent, with or without acidification, as shown in Table 4 .

Figure 1
Means of the actual and predicted total anthocyanin content (mg/100 mL of the extract) of the diluted and undiluted phenolic extracts prepared with acidified (HCL) 70% ethanol and 70% ethanol. The bars represent the standard deviation.

The maximum variation between the actual and predicted anthocyanin content obtained was 5% for phenolic extracts produced with 70% ethanol and acidified 70% ethanol diluted 20 times. It was not possible to fit a multiple linear regression model with r² greater than 0.80 in the case of phenolic extracts produced with acidified 70% ethanol, diluted 2 and 5 times, and phenolic extracts produced with 70% ethanol diluted 2 times.

This study proved that the spectrophotometric method for quantification of anthocyanins in fruits and vegetables could be perfectly replaced by the colorimetric method. The use of the colorimetric method, in addition to reducing costs and time, reduces the amount of toxic and non-toxic reagents used in traditional methods. When the hue (h*) and saturation (C*) are calculated, it is possible to further reduce the analysis time, since equations with high R² were obtained for phenolic extracts, requiring no dilutions. Furthermore, tristimulus colorimeters allow a qualitative analysis of the extracts, being an advantage over the quantitative method based on the measurement of the absorbance at 535 nm. Thus, the present study indicates the reliability and feasibility of predicting the total anthocyanin content of fruits and vegetables using colorimetric coordinates, providing an alternative to the traditional method.

4 Conclusions

Multiple linear regression models with high r² were obtained and can be used to predict the total anthocyanin content of the fruits and vegetables used in this study, facilitating the definition of the harvest point and, as such, can be used as an important starting point to define the quality of fresh and processed products, which is related to the content of anthocyanins.

The tristimulus colorimeter allows a qualitative analysis of phenolic extracts, which is an advantage over the quantitative method based on absorbance measurement at 535 nm, because of its speed, low cost and no need of specialized reagents. The results confirm the reliability and feasibility of predicting the total anthocyanin content of different fruits and vegetables using colorimetry.

Acknowledgements

The authors would like to thank the research support agencies: Capes, Fapemig and Cnpq for financial support.

Pratical Aplicattion: The use of colorimeters' as an important tool for the quantification of anthocyanins of fruits and vegetables.

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Publication Dates

Publication in this collection
20 Aug 2018
Date of issue
Apr-Jun 2019

History

Received
28 Sept 2017
Accepted
27 May 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Pratical Aplicattion: The use of colorimeters' as an important tool for the quantification of anthocyanins of fruits and vegetables.

Vegetal	Anthocyanin content (mg·100 mL^-1 of the extract)
	70% acidified ethanol			70% ethanol
	Min ^a a Lowest anthocyanin content (mg/100 mL of the extract) obtained; b Highest anthocyanin content (mg/100 mL of the extract) obtained; ns Average values do not differ among themselves by the F test, at 5% probability.	Maxb	AVERAGE	Min ^a a Lowest anthocyanin content (mg/100 mL of the extract) obtained; b Highest anthocyanin content (mg/100 mL of the extract) obtained; ns Average values do not differ among themselves by the F test, at 5% probability.	Maxb	AVERAGE
Açaí	6.10	11.87	8.35	4.64	9.15	6.88 ns
Plum	11.60	12.15	11.80	6.92	7.19	7.06 ^* * Significant for F test, p < 0.05, within lines.
Blackberry	2.53	2.78	2.64	2.61	4.53	3.85 ^* * Significant for F test, p < 0.05, within lines.
Eggplant	3.44	3.81	3.65	0.54	0.71	0.63 ^* * Significant for F test, p < 0.05, within lines.
Camu-camu	0.29	4.20	3.73	4.10	4.68	4.39 ^* * Significant for F test, p < 0.05, within lines.
Raspberry	3.44	3.68	3.59	2.32	3.15	2.83 ^* * Significant for F test, p < 0.05, within lines.
Jabuticaba	5.24	6.52	6.08	7.48	8.75	7.97 ^* * Significant for F test, p < 0.05, within lines.
Jussara	287.84	346.91	325.86	244.39	338.08	288.11 ns
Blueberry	6.53	11.36	8.60	5.77	8.46	7.08 ns
Strawberry	0.68	0.70	0.70	1.08	1.13	1.10 ^* * Significant for F test, p < 0.05, within lines.
Red pitaya	0.56	1.37	0.76	2.44	2.57	2.50 ^* * Significant for F test, p < 0.05, within lines.
Purple Cabbage	5.94	7.11	6.54	0.21	0.23	0.22 ^* * Significant for F test, p < 0.05, within lines.
Red Globe Grape	5.75	6.26	6.00	7.10	8.40	7.66 ^* * Significant for F test, p < 0.05, within lines.

Solvent	Vegetable	L*	a*	b*	C*	h*
70% Acidified Ethanol	Açaí	26.48 ^Ea	7.08 ^Fa	1.55 ^Fa	7.25 ^Ga	77.80 ^Aa
	Plum	29.21 ^Db	17.31 ^Eb	5.50 ^Eb	18.16 ^Fb	72.47 ^ABa
	Blackberry	37.56 ^Ba	37.08 ^Aa	18.05 ^BCa	41.24 ^Ba	64.04 ^Db
	Eggplant	29.24 ^Db	21.04 ^DEa	7.00 ^Eb	22.17 ^EFb	71.59 ^ABCa
	Camu-camu	37.10 ^Bb	39.54 ^Aa	19.90 ^Ba	44.27 ^Aba	63.28 ^Db
	Raspberry	37.49 ^Bb	39.33 ^Aa	19.70 ^Ba	44.00 ^Aba	63.35 ^Db
	Jabuticaba	35.98 ^Ba	32.59 ^Ba	15.47 ^CDa	36.08 ^Ca	64.64 ^CDb
	Jussara	25.56 ^Ea	0.25 ^Ga	0.57 ^Fa	0.63 ^Ha	24.73 ^Fa
	Blueberry	30.48 ^Da	21.94 ^Da	6.96 ^Ea	23.02 ^Ea	72.39 ^ABb
	Strawberry	44.53 ^Ab	38.48 ^Aa	26.42 ^Aa	46.68 ^Aa	55.53 ^Eb
	Red pitaya	33.90 ^Ca	26.11 ^Cb	-5.48 ^Gb	27.13 ^Db	74.29 ^ABb
	Purple Cabbage	36.14 ^Bb	38.39 ^Aa	17.90 ^BCa	42.36 ^Ba	64.99 ^CDb
	Red Globe Grape	33.02 ^Cb	29.94 ^Ba	12.05 ^Da	32.28 ^Ca	68.08 ^BCDa
	Açaí	25.01 ^Ha	4.58 ^Ia	1.04 ^Ea	4.71 ^Ib	78.32 ^BCDa
70% ethanol	Plum	33.02 ^FGa	25.27 ^Da	10.50 ^Ba	27.36 ^Da	67.43 ^Fb
	Blackberry	39.93 ^CDa	29.44 ^Cb	-1.31 ^Fb	29.58 ^Cb	85.19 ^Aa
	Eggplant	49.58 ^Ba	3.79 ^Ib	26.97 ^Aa	27.27 ^Da	8.14 ^Gb
	Camu-camu	37.73 ^DEa	36.25 ^Ab	9.20 ^Bb	37.41 ^Ab	75.75 ^CDEa
	Raspberry	40.55 ^Ca	36.04 ^ABb	6.42 ^CDb	36.62 ^Ab	79.90 ^BCa
	Jabuticaba	30.94 ^Gb	19.87 ^Fb	6.60 ^Cb	20.94 ^Fb	71.62 ^EFa
	Jussara	25.88 ^Ha	0.00 ^Jb	-0.69 ^EFa	0.69 ^Ja	7.67 ^Gb
	Blueberry	31.00 ^Ga	19.51 ^Fb	5.54 ^CDb	20.28 ^Fb	74.17 ^DEa
	Strawberry	57.50 ^Aa	13.56 ^Gb	0.63 ^EFb	13.59 ^Gb	85.79 ^Aa
	Red pitaya	33.77 ^Fa	33.98 ^Ba	4.19 ^Da	34.24 ^Ba	82.98 ^ABa
	Purple Cabbage	57.96 ^Aa	7.16 ^Hb	-1.41 ^Fb	7.31 ^Hb	78.96 ^BCDa
	Red Globe Grape	35.21 ^EFa	22.47 ^Eb	9.11 ^Bb	24.25 ^Eb	67.93 ^Fa

SOLVENT	PHENOLIC EXTRACTS	L*	r₁	a*	r₂	b*	r₃	C*	r₄	h*	r₅
Acidified (HCl) 70% ethanol	Without dilution	33.59 ± 1.47	-0.47 ^ Correlation is significant at the 0.01 level.	26.85 ± 3.56	-0.63 ^ Correlation is significant at the 0.01 level.	11.11 ± 2.61	-0.37 ^ Correlation is significant at the 0.01 level.	29.75 ± 1.81	-0.60 ^ Correlation is significant at the 0.01 level.	64.30 ± 1.66	-0.85 ^ Correlation is significant at the 0.01 level.
	1:2	37.68 ± 1.85	-0.52 ^ Correlation is significant at the 0.01 level.	32.04 ± 3.31	-0.76 ^ Correlation is significant at the 0.01 level.	11.24 ± 2.46	-0.37 ^ Correlation is significant at the 0.01 level.	34.74 ± 1.60	-0.75 ^ Correlation is significant at the 0.01 level.	68.79 ± 0.69	0.64 ^ Correlation is significant at the 0.01 level.
	1:5	43.38 ± 2.44	-0.56 ^ Correlation is significant at the 0.01 level.	35.15 ± 3.59	-0.61 ^ Correlation is significant at the 0.01 level.	7.06 ± 2.88	0.39 ^ Correlation is significant at the 0.01 level.	38.44 ± 2.32	0.01	75.92 ± 1.64	-0.30 ^* * Correlation is significant at the 0.05 level;
	1:10	48.71 ± 2.73	-0.60 ^ Correlation is significant at the 0.01 level.	33.16 ± 3.70	-0.35 ^ Correlation is significant at the 0.01 level.	-1.19 ± 1.82	0.25 ^* * Correlation is significant at the 0.05 level;	33.78 ± 1.61	-0.36 ^ Correlation is significant at the 0.01 level.	78.14 ± 0.98	-0.11
	1:20	54.50 ± 2.75	-0.73 ^ Correlation is significant at the 0.01 level.	26.29 ± 3.37	-0.03	-3.75 ± 1.54	0.62 ^ Correlation is significant at the 0.01 level.	27.07 ± 1.49	-0.01	75.53 ± 1.11	-0.10
70% Ethanol	Without dilution	38.31 ± 2.98	-0.37 ^ Correlation is significant at the 0.01 level.	19.38 ± 3.52	-0.44 ^ Correlation is significant at the 0.01 level.	5.90 ± 2.10	-0.25 ^* * Correlation is significant at the 0.05 level;	21.87 ± 1.47	-0.52 ^ Correlation is significant at the 0.01 level.	66.15 ± 3.24	-0.65 ^ Correlation is significant at the 0.01 level.
	1:2	45.44 ± 3.32	-0.51 ^ Correlation is significant at the 0.01 level.	19.02 ± 3.78	-0.40 ^ Correlation is significant at the 0.01 level.	3.24 ± 1.99	-0.15	21.00 ± 1.55	-0.46 ^ Correlation is significant at the 0.01 level.	52.81 ± 6.00	-0.20
	1:5	55.58 ± 3.29	-0.74 ^ Correlation is significant at the 0.01 level.	12.26 ± 3.42	-0.23	1.47 ± 2.36	-0.04	14.43 ± 1.55	-0.28 ^* * Correlation is significant at the 0.05 level;	60.47 ± 3.34	0.28 ^* * Correlation is significant at the 0.05 level;
	1:10	61.41 ± 3.21	-0.86 ^ Correlation is significant at the 0.01 level.	6.98 ± 2.54	-0.06	1.02 ± 1.97	0.02	9.08 ± 1.21	-0.06	60.88 ± 3.17	0.23
	1:20	64.86 ± 3.10	-0.95 ^ Correlation is significant at the 0.01 level.	3.77 ± 1.82	0.49 ^ Correlation is significant at the 0.01 level.	0.96 ± 1.28	0.15	5.52 ± 0.84	0.41 ^ Correlation is significant at the 0.01 level.	55.09 ± 3.24	0.25 ^* * Correlation is significant at the 0.05 level;

Solvent	Dilution	Adjusted equation	R²
HCl Ethanol	Without dilution	$y = 474.31 - 5.89 h * - 10.824 C * + 9.586 a *$	0.99
	1:10	$y = 52.553 - 0.728 L * - 0.431 a *$	0.80
		$y = 54.029 - 0.743 L * - 0.453 C *$	0.82
	1:20	$y = 37.878 - 0.533 L * - 0.275 a *$	0.88
70%Ethanol	Without dilution	$y = 312.33 - 3.984 h * - 6.751 b * + 5.556 a * - 4.146 C *$	0.98
	1:5	$y = 90.877 - 1.316 L * - 0.877 a * - 0.669 b *$	0.92
		$y = 94.082 - 1.326 L * - 0.479 a * - 0.781 b * - 0.556 C *$	0.98
	1:10	$y = 46.549 - 0.663 L * - 0.419 a * - 0.303 b *$	0.97
		$y = 47.986 - 0.675 L * - 0.367 a * - 0.315 b * - 0.138 C *$	0.99
	1:20	$y = 32.415 - 0.459 L * - 0.283 a * - 0.184 b *$	0.97
		$y = 27.314 - 0.410 L * - 0.201 a * + 0.024 h *$	0.98

Brasil

Brasil

Chromatic analysis for predicting anthocyanin content in fruits and vegetables

Abstract

1 Introduction

2 Material and Methods

2.1 Fruits and vegetables used in the study

2.2 Phenolic extraction and total anthocyanins determination

2.3 Colorimetric characterization of the phenolic extracts

2.4 Correlations between anthocyanin content and colorimetric coordinates

2.5 Development of prediction models

2.6 Statistical Analysis

3 Results and discussion

3.1 Total anthocyanin content

3.2 Colorimetric characterization of the phenolic extracts

3.3 Correlations between total anthocyanin content and colorimetric coordinates

3.4 Development of prediction models based on colorimetric coordinates

4 Conclusions

Acknowledgements

References

Publication Dates

History