Kinetic and Thermodynamic Characteristics of Thermal Degradation of Anthocyanins from Strawberry and Blueberry Commercial Juices

Chemia Naissensis Volume 3, No.2 (2020) (стр. 46-66) 

АУТОР(И) / AUTHOR(S): Milan N. Mitić

Е-АДРЕСА / E-MAIL: milamitic83@yahoo.com

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DOI: 10.46793/ChemN3.2.046M

САЖЕТАК / ABSTRACT:

Thermal stabilities of anthocyanins in strawberry and blueberry commercial juices were studied over the temperatures 75, 85 and 95 oC. Results indicated that the thermal degradation of anthocyanins followed the first-order reaction kinetics. The temperature-dependent degradation was adequately modeled on the Arrhenius equation. During heating, anthocyanins in the strawberry juice degraded faster than in blueberry juice, with the activation energies of 74.16 kJ/mol and 65.75 kJ/mol, respectively. Cyanidin-3-glucoside (cyd-3-glu) was more susceptible to the thermal treatment than pelargonidin glycosides in strawberry juice. Delphinidin glycosides were more susceptible to the thermal treatment than cyanidin glycosides in blueberry juice. However, cyd-3-glu in strawberry juice was more sensitive to the thermal treatment than in blueberry juice. Obtained results for activation enthalpies indicated that the degradation process was endothermic and Gibbs free energy of activation indicated that they were not spontaneous.

КЉУЧНЕ РЕЧИ / KEYWORDS:

Thermal degradation, anthocyanins, degradation kinetics, blueberry juice, strawberry juice

ЛИТЕРАТУРА / REFERENCES:

  • Al-Zubaidy, M.M.I., & Khalil, R.A. (2007). Kinetic and prediction studies of ascorbic acid degradation in normal and concentrate local lemon juice during storage. Food Chemistry, 101, 254-259.
  • Borsato, D., Galvan, D., Pereira, J.L., Orives, J.R., Angilelli, K.G., & Coppo, R.L. (2014). Kinetic and thermodynamic parameters of biodiesel oxidation with synthetic antioxidants: simplex centroid mixture design. Journal of the Brazilian Chemical Society, 25, 1984-1992.
  • Casati, B., Baeza, R., Sanchez, V., Catalano, A., Lopez, P., & Zamora, M.C. (2015). Thermal degradation kinetics of monomeric anthocyanins, colour changes and storage effect in elderberry juices. Journal of Berry Research, 5, 29-39.
  • Cemeroglu, B., Velioglu, S., & Isik, S. (1994). Degradation kinetics of anthocyanins in sour cherry juice and concentrate. Journal of Food Science, 59, 1216-1218.
  • Cisse, , Vaillant, F., Acosta, O., Dhuique-Mayer, C., & Dornier, M. (2009). Thermal degradation kinetics of anthocyanins from blood orange, blackberry and roselle using Arrhenius, eyring and ball models. Journal of Agricultural and Food Chemistry, 57, 6285-6291.
  • Clifford, M.N. (2000). Anthocyanins nature, occurrence and dietary burden. Journal of the Science of the Food and Agriculture, 80, 1063-1072.
  • Da Silva, F.L., Escribano-Bailón, M.T., Alonso, J.J.P., Rivas-Gonzalo, J.C., & Buelga, S.C. (2007). Anthocyanin pigments in strawberry. LWT-Food Science and Technology, 40, 374-382.
  • 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 Chemical Toxicology, 47, 837-847.
  • Dalisman, G., Arslan, E., & Toklucu, A.K. (2015). Kinetic analysis of anthocyanin degradation and polymeric colour formation in grape juice during heating. Czech Journal of Food Science, 33, 103-108.
  • Espin, J.C., Soler-Rivas, C., Wichers, H., & Garcia-Viguera, C. (2000). Anthocyanin-based natural colorants։ a new source of antiradical activity for food stuff. Journal of Agricultural and Food Chemistry, 48, 1588-1592.
  • Gerard, V., Ay, E., Morlet-Savary, F., Graff, B., Galopin, C., Orgen, T., Mulilangi, W., & Valevee, J. (2019). Thermal and photochemical stability anthocyanins from black carrot, grape juice, and purple sweet potato in model beverages in the presence of ascorbic acid. Journal of Agricultural and Food Chemistry, 67, 5647-5660.
  • Hillmann, M.C.R., Burin, V.M., & Bordignon-Luiz, M.T. (2011). Thermal degradation kinetics of anthocyanins in grape juice and concentrate. International Journal of Food Science and Technology, 46, 1997-2000.
  • Hou, Z., Qin, P., Zhang, Y., Cui, S., & Ren, G. (2013). Identification of anthocyanins isolated from black rice (Oryza sativa ) and their degradation kinetics. Food Research International, 50, 691-697.
  • Jakobek, L., Serugi, M., Medvidovic-Kosanovic, M., & Novak, I. (2007). Anthocyanin content and antioxidante activity of various red fruit juices. Deutsche Lebensmitlel-Rundschau, 2, 58-64.
  • Jimenez, , Bohuon, P., Lima, J., Dornier, M., Vaillant, F., & Perez, A.M. (2010). Kinetics of anthocyanins degradation and browning in reconstituted blackberry juice treated at high temperatures (100-180°C). Journal of Agricultural and Food Chemistry, 58, 2314-2322.
  • Kechinski, P., Guimaraes, P.V.R., Norena, C.P.Z., Tessaro, I.C., & Marczak, L.D.F. (2010). Degradation kinetics of anthocyanin in blueberry juice during thermal treatment. Journal of Food Science, 75, C173- 176.
  • Liu, J., Dong, N., Wang, Q., Li, J., Qian, G., Fan, H., & Zhao, G. (2014). Thermal degradation kinetics of anthocyanins from Chinese red radish (Raphanus sativus ) in various juice beverages. European Food Research Technology, 238, 177-184.
  • Mercali, G.D., Jaeschke, D.P., Tessaro, I.C., & Marczak, L.D.F. (2013). Degradation kinetics of anthocyanins in acerola pulp: Comparison between ohmic and conventional heat treatment. Food Chemistry, 136, 853-857.
  • Moldovan, B., & David, L. (2020). Influence of different sweeteners on the stability of anthocyanins from cornelian cherry juice. Foods, 9, 1266, doi:10.3390/foods9091266.
  • Obón, J.M., Díaz-García, M.C., & Castellar, M.R. (2011). Red fruit juice quality and authenticity control by HPLC. Journal of Food Composition and Analysis, 24, 760-771.
  • Park, J.N., & Kim, J.H. (2017). Kinetic and thermodynamic characteristics of fractional precipitation of (+)-dihydromyricetin. Process Biochemistry, 53, 224-231.
  • Prior, R.L., Lazarus, S.A., Cao, G., Muccitelli, H., & Hammerstone, J.F. (2001). Identification of procyanidins and anthocyanins in blueberry and cranberries (Vaccinium ) using high performance liquid chromatography/mass spectrometry. Journal of Agricultural and Food Chemistry, 49, 1270-1276.
  • Stój, A., Malik, A., & Targónski, Z. (2006). Comparative analysis of anthocyanin composition of juices obtained from selected species of berry fruits. Polish Journal of Food and Nutrition Science, 15, 401-407. Svensson, D. (2010). Effects of heat treatment and additives on the anthocyanin content in blackcurrants and its relation to colour and texture. MSc Thesis. Chalmers University of Technology.
  • Szaloki-Darko, L., Vegvari, G., Ladanyi, M., Ficzek, G., & Steger-Mate, M. (2015). Degradation of anthocyanin content in sour cherry juice during heat treatment. Food Technology and Biotechnology, 53, 354-360.
  • Turturica, , Stanciuc, N., Muresan, C., Rapeanu, G., & Croitoru, C. (2018). Thermal degradation of plum anthocyanins: comparison of kinetics from simple to natural systems. Journal of Food Quality, 2018, Article ID 1598756, https://doi.org/10.1155/2018/1598756.
  • Verbeyst, L., Van Crombruggen, K., Van der Plancken, I., Hendrickx, M., & Van Loey, A. (2011). Anthocyanin degradation kinetics during thermal and high pressure treatments of raspberries. Journal of Food Engineering, 105, 513-521.
  • Wang, D., & Xu, S.Y. (2007). Degradation kinetics of anthocyanins in blackberry juice and concentrate. Journal of Food Engineering, 82, 271.
  • Wu, X., & Prior, R. (2005). Systematic identification and characterization of anthocyanins by HPLC–ESI- MS/MS in common fruits in the United States: Fruits and berries. Journal of Agricultural and Food Chemistry, 53, 2589-2599.
  • Zhao, , Li, Y., Xu, X., Wu, J., Liao, X., & Chen, F. (2012). Degradation kinetics of malvidin-3-glucoside and malvidin-3,5-diglucoside exposed to microwave treatment. Journal of Agricultural and Food Chemistry, 61, 373-378.