Abstract
Recent findings suggested that using frozen material for meat processing leads to products with increased protein oxidation rates and impaired quality traits. Therefore, the effects of frozen storage and the addition of a phenolic-rich dog rose extract (Rosa canina L.; RC), on lipid and protein oxidation, moisture losses, color stability, and hardness of beef patties were investigated. Protein oxidation was assessed by means of tryptophan loss and the formation of specific lysine oxidation products: α-aminoadipic semialdehyde (AAS), α-aminoadipic acid (AAA), and Schiff bases. Frozen storage increased proteins susceptibility towards oxidation during successive technological processes. The addition of the RC extract inhibited the formation of AAS, AAA, and had an antioxidant effect towards tryptophan oxidation, but promoted the formation of Schiff bases and incremented the hardness of beef patties. The antioxidant effect may be attributed to the phenolic compounds, mainly procyanidins, found on the RC extract. Further knowledge on the interactions between phenolics and proteins is needed to optimize the application of these antioxidants against meat protein oxidation.
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References
Akagawa, M., & Suyama, K. (2001). Amine oxidase-like activity of polyphenols: Mechanism and properties. European Journal of Biochemistry, 268, 1953–1963.
Bourne, M. C. (1978). Texture profile analysis. Food Technology, 33, 62–66.
De Freitas, V., & Mateus, N. (2001). Structural features of procyanidin interactions with salivary proteins. Journal of Agriculture and Food Chemistry, 49, 940–945.
Deaville, E. R., Green, R. J., Mueller-Harvey, I., Willoughby, I., & Frazier, R. A. (2007). Hydrolyzable tannin structures influence relative globular and random coil protein binding strengths. Journal of Agriculture and Food Chemistry, 55, 4554–4561.
Estévez, M. (2011). Protein carbonyls in meat systems: A review. Meat Science, 89, 259–279.
Estévez, M., & Heinonen, M. (2010). Effect of phenolic compounds on the formation of a-aminoadipic and γ-glutamic semialdehydes from myofibrillar proteins oxidised by copper, iron, and myoglobin. Journal of Agricultural and Food Chemistry, 58, 4448–4455.
Estévez, M., Ventanas, S., & Cava, R. (2005). Protein oxidation in frankfurters with increasing levels of added rosemary essential oil: Effect on colour and texture deterioration. Journal of Food Science, 70, 427–432.
Estévez, M., Kylli, P., Puolanne, E., Kivikari, R., & Heinonen, M. (2008). Fluorescence spectroscopy as a novel approach for the assessment of myofibrillar protein oxidation in oil-in-water emulsions. Meat Science, 80, 1290–1296.
Estévez, M., Ventanas, S., Heinonen, M., & Puolanne, E. (2011). Protein carbonylation and water-holding capacity of pork subjected to frozen storage: Effect of muscle type, premincing, and packaging. Journal of Agricultural and Food Chemistry, 59, 5435–5443.
Filgueras, R. S., Gatellier, P., Ferreira, C., Zambiazi, R. C., & Santé-Lhoutellier, V. (2011). Nutritional value and digestion rate of rhea meat proteins in association with storage and cooking processes. Meat Science, 89, 6–12.
Ganhão, R., Estévez, M., Kylli, P., Heinonen, M., & Morcuende, D. (2010a). Characterization of selected wild Mediterranean fruits and comparative efficacy as inhibitors of oxidative reactions in emulsified raw pork burger patties. Journal of Agriculture and Food Chemistry, 58, 8854–8861.
Ganhão, R., Estévez, M., & Morcuende, D. (2010b). Protein oxidation in emulsified cooked burger patties with added fruit extracts: Influence on colour and texture deterioration during chill storage. Meat Science, 85, 402–409.
Halliwell, B. (2008). Are polyphenols antioxidants or pro-oxidants? What do we learn from cell culture and in vivo studies? Archives of Biochemistry and Biophysics, 476, 107–112.
Heim, K. E., Tagliaferro, A. R., & Bobilya, D. J. (2002). Flavonoid antioxidants: chemistry, metabolism and structure–activity relationships. The Journal of Nutritional Biochemistry, 13, 572–584.
Hidalgo, F. J., & Zamora, R. (2000). Modification of bovine serum albumin structure following reaction with 4,5(E)-Epoxy-2(E)-heptenal. Chemical Research in Toxicology, 13, 501–508.
Hidalgo, F. J., Alaiz, M., & Zamora, R. (1998). A spectrophotometric method for the determination of proteins damaged by oxidized lipids. Analitycal Biochemistry, 262, 129–136.
Huang, L., Xiong, Y. L., Kong, B., Huang, X., & Li, J. (2013). Influence of storage temperature and duration on lipid and protein oxidation and flavour changes in frozen pork dumpling filler. Meat Science, 95, 295–301.
Hui, Y. H., Cornillon, P., Guerrero-Legarreta, I., Lim Miang, H., Murell, K. D., & Wai-Kit, N. (2004). Handbook of frozen foods. New York: Marcel Dekker, Inc.
Ladikos, D., & Lougovois, V. (1990). Lipid oxidation in muscle foods: A review. Food Chemistry, 35, 295–314.
Leygonie, C., Britz, T. J., & Hoffman, L. C. (2012). Impact of freezing and thawing on the quality of meat: Review. Meat Science, 91, 93–98.
Lund, M. N., Heinonen, M., Baron, C. P., & Estévez, M. (2011). Protein oxidation in muscle foods: A review. Molecular Nutrition and Food Research, 55, 83–95.
Mancini, R. A., & Hunt, M. C. (2005). Current research in meat color. Meat Science, 71, 100–121.
Min, B., & Ahn, D. U. (2005). Mechanism of lipid peroxidation in meat and meat products—A review. Food Science and Biotechnology, 14, 152–163.
Ozdal, T., Capanoglu, E., & Altay, F. (2013). A review on protein–phenolic interactions and associated changes. Food Research International, 51, 954–970.
Petrović, L., Grujić, R., & Petrović, M. (1993). Definition of the optimal freezing rate-2. Investigation of the physico-chemical properties of beef M. longissimus dorsi frozen at different freezing rates. Meat Science, 33, 319–331.
Rawel, H. M., Kroll, J., & Rohn, S. (2001). Reactions of phenolic substances with lysozyme physicochemical characterization and proteolytic digestion of the derivatives. Food Chemistry, 72, 59–71.
Rohn, S., Rawel, H. M., & Kroll, J. (2004). Antioxidant activity of protein bound quercetin. Journal of Agriculture and Food Chemistry, 52, 4725–4729.
Scalbert, A., Johnson, I. T., & Saltmarsh, M. (2005). Polyphenols: Antioxidants and beyond. The American Journal of Clinical Nutrition, 81, 215S–217S.
Soyer, A., Özalp, B., Dalmıs, U., & Bilgin, V. (2010). Effects of freezing temperature and duration of frozen storage on lipid and protein oxidation in chicken meat. Food Chemistry, 120, 1025–1030.
SPSS. (1999). SPSS for windows: Advanced statistic release. Chicago: SPSS.
Stadtman, E. R. (2004). Role of oxidant species in aging. Current Medicinal Chemistry, 11, 1105–1112.
Timm-Heinrich, M., Eymard, S., Baron, C. P., Nielsen, H. H., & Jacobsen, C. (2013). Oxidative changes during ice storage of rainbow trout (Oncorhynchus mykiss) fed different ratios of marine and vegetable feed ingredients. Food Chemistry, 136, 1220–1230.
Utrera, M., & Estévez, M. (2012). Oxidation of myofibrillar proteins and impaired functionality: Underlying mechanisms of the carbonylation pathway. Journal of Agricultural and Food Chemistry, 60, 8002–8011.
Utrera, M., & Estévez, M. (2013). Impact of trolox, quercetin, genistein and gallic acid on the oxidative damage to myofibrillar proteins: The carbonylation pathway. Food Chemistry, 141, 4000–4009.
Utrera, M., Armenteros, M., Ventanas, S., Solano, F., & Estévez, M. (2012a). Pre-freezing raw hams affects quality traits in cooked hams: Potential influence of protein oxidation. Meat Science, 92, 596–603.
Utrera, M., Rodríguez-Carpena, J. G., Morcuende, D., & Estévez, M. (2012b). Formation of lysine-derived oxidation products and loss of tryptophan during processing of porcine patties with added avocado byproducts. Journal of Agricultural and Food Chemistry, 60, 3917–3926.
Utrera, M., Parra, V., & Estévez, M. (2014a). Protein oxidation during frozen storage and subsequent processing of different beef muscles. Meat Science, 96, 812–820.
Utrera, M., Morcuende, D., & Estévez, M. (2014b). Temperature of frozen storage affects the nature and consequences of protein oxidation and the interactions with lipids in beef patties. Meat Science, 96, 1250–1257.
Utrera, M., Morcuende, D., & Estévez, M. (2014c). Fat content has a significant impact on protein oxidation occurred during frozen storage of beef patties. LWT - Food Science and Technology, 56, 62–68.
Vijayalakshmi, G., Adinarayana, M., & Rao, P. J. (2010). Kinetics and mechanisms of oxidation of some antioxidants with photochemically generated tert-butoxyl radicals. Indian Journal of Biochemistry & Biophysics, 47, 292–297.
Vossen, E., Utrera, M., De Smet, S., Morcuende, D., & Estévez, M. (2012). Dog rose (Rosa canina L.) as a functional ingredient in porcine frankfurters without added sodium ascorbate and sodium nitrite. Meat Science, 92, 451–457.
Wang, H., Cao, G., & Prior, R. L. (1997). Oxygen radical absorbing capacity of anthocyanins. Journal of Agriculture and Food Chemistry, 45, 304–309.
Xia, X., Kong, B., Liu, Q., & Liu, J. (2009). Physicochemical change and protein oxidation in porcine longissimus dorsi as influenced by different freeze thaw cycles. Meat Science, 83, 239–245.
Zaritzky, N. (2012). Physical–chemical principles in freezing. In D. W. Sun (Ed.), Handbook of frozen food processing and packaging (pp. 3–38). Boca Raton: CRC Press.
Acknowledgments
Mario Estévez thanks the Spanish Ministry of Science and Innovation for the contract through the “Ramón y Cajal (RYC-2009-03901)” program and the support through the project “Protein oxidation in frozen meat and dry-cured products: mechanisms, consequences and development of antioxidant strategies” (AGL2010-15134). Mario Estévez thanks the European Community for the economical support from the Marie Curie Reintegration (ERG) Fellowship (PERG-GA-2009-248959—Pox-MEAT). Mariana Utrera thanks the University of Extremadura (Uex) for the pre-doctoral grant (Human Resources Recruitment Program “C Action”).
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Utrera, M., Morcuende, D., Ganhão, R. et al. Role of Phenolics Extracting from Rosa canina L. on Meat Protein Oxidation During Frozen Storage and Beef Patties Processing. Food Bioprocess Technol 8, 854–864 (2015). https://doi.org/10.1007/s11947-014-1450-3
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DOI: https://doi.org/10.1007/s11947-014-1450-3