Back Article

Cai D, Li X, Chen J, Jiang X, Ma X, et al. 2022. A comprehensive review on innovative and advanced stabilization approaches of anthocyanin by modifying structure and controlling environmental factors. Food Chemistry 366:130611

He F, Liang NN, Mu L, Pan QH, Wang J, et al. 2012. Anthocyanins and their variation in red wines I. monomeric anthocyanins and their color expression. Molecules 17:1571−601

del Alamo-Sanza M, Nevares I. 2018. Oak wine barrel as an active vessel: A critical review of past and current knowledge. Critical Reviews in Food Science and Nutrition 58:2711−26

Nagel CW, Wulf LW. 1979. Changes in the anthocyanins, flavonoids and hydroxycinnamic acid-esters during fermentation and aging of merlot and cabernet sauvignon. American Journal of Enology and Viticulture 30:111−16

Dipalmo T, Crupi P, Pati S, Clodoveo ML, Di Luccia A. 2016. Studying the evolution of anthocyanin-derived pigments in a typical red wine of Southern Italy to assess its resistance to aging. Lwt - Food Science and Technology 71:1−9

Gutiérrez IH, Lorenzo ESP, Espinosa AV. 2005. Phenolic composition and magnitude of copigmentation in young and shortly aged red wines made from the cultivars, Cabernet Sauvignon, Cencibel, and Syrah. Food Chemistry 92:269−83

Enaru B, Drețcanu G, Pop TD, Stǎnilǎ A, Diaconeasa Z. 2021. Anthocyanins: Factors Affecting Their Stability and Degradation. Antioxidants 10:1967

Ali HM, Almagribi W, Al-Rashidi MN. 2016. Antiradical and reductant activities of anthocyanidins and anthocyanins, structure-activity relationship and synthesis. Food Chemistry 194:1275−82

Brauch JE, Kroner M, Schweiggert RM, Carle R. 2015. Studies into the stability of 3-O-Glycosylated and 3,5-O-diglycosylated anthocyanins in differently purified liquid and dried maqui (Aristotelia chilensis (Mol.) Stuntz) preparations during storage and thermal treatment. Journal of Agricultural and Food Chemistry 63:8705−14

Talcott ST, Lee JH. 2002. Ellagic acid and flavonoid antioxidant content of muscadine wine and juice. Journal of Agricultural and Food Chemistry 50:3186−92

Oliveira H, Basílio N, Pina F, Fernandes I, de Freitas V, Mateus N. 2019. Purple-fleshed sweet potato acylated anthocyanins: Equilibrium network and photophysical properties. Food Chemistry 288:386−94

Pomar F, Novo M, Masa A. 2005. Varietal differences among the anthocyanin profiles of 50 red table grape cultivars studied by high performance liquid chromatography. Journal of Chromatography A 1094:34−41

Lukić I, Radeka S, Budić-Leto I, Bubola M, Vrhovsek U. 2019. Targeted UPLC-QqQ-MS/MS profiling of phenolic compounds for differentiation of monovarietal wines and corroboration of particular varietal typicity concepts. Food Chemistry 300:125251

Zhao X, Zhang X, He X, Duan C, He F. 2021. Acetylation of Malvidin-3-O-glucoside Impedes Intermolecular Copigmentation: Experimental and Theoretical Investigations. Journal of Agricultural and Food Chemistry 69:7733−41

Mendoza J, Oliveira J, Araújo P, Basílio N, Teixeira N, et al. 2020. The peculiarity of malvidin 3-O-(6-O-p-coumaroyl) glucoside aggregation. Intra and intermolecular interactions. Dyes and Pigments 180:108382

Matsufuji H, Otsuki T, Takeda T, Chino M, Takeda M. 2003. Identification of reaction products of acylated anthocyanins from red radish with peroxyl radicals. Journal of Agricultural and Food Chemistry 51:5188−88

Waterhouse AL, Zhu J. 2020. A quarter century of wine pigment discovery. Journal of the Science of Food and Agriculture 100:5093−101

Hayasaka Y, Kennedy JA. 2003. Mass spectrometric evidence for the formation of pigmented polymers in red wine. Australian Journal of Grape and Wine Research 9:210−20

Es-Safi NE, Cheynier V, Moutounet M. 2002. Role of aldehydic derivatives in the condensation of phenolic compounds with emphasis on the sensorial properties of fruit-derived foods. Journal of Agricultural and Food Chemistry 50:5571−85

Pissarra J, Lourenço S, González-Paramás AM, Mateus N, Santos-Buelga C, et al. 2004. Formation of new anthocyanin-alkyl/aryl-flavanol pigments in model solutions. Analytica Chimica Acta 513:215−21

Salas E, Fulcrand H, Meudec E, Cheynier V. 2003. Reactions of anthocyanins and tannins in model solutions. Journal of Agricultural and Food Chemistry 51:7951−61

Salas E, Atanasova V, Poncet-Legrand C, Meudec E, Mazauric JP, et al. 2004. Demonstration of the occurrence of flavanol-anthocyanin adducts in wine and in model solutions. Analytica Chimica Acta 513:325−32

Berrueta LA, Rasines-Perea Z, Prieto-Perea N, Asensio-Regalado C, Alonso-Salces RM, et al. 2020. Formation and evolution profiles of anthocyanin derivatives and tannins during fermentations and aging of red wines. European Food Research and Technology 246:149−65

Morata A, Loira I, Heras JM, Callejo MJ, Tesfaye W, et al. 2016. Yeast influence on the formation of stable pigments in red winemaking. Food Chemistry 197:686−91

Liu S, Laaksonen O, Yang W, Zhang B, Yang B. 2020. Pyranoanthocyanins in bilberry (Vaccinium myrtillus L.) wines fermented with Schizosaccharomyces pombe and their evolution during aging. Food Chemistry 305:125438

Alcalde-Eon C, Escribano-Bailón MT, García-Estévez I. 2022. Role of oak ellagitannins in the synthesis of Vitisin A and in the degradation of malvidin 3-O-Glucoside: An approach in wine-like model systems. Journal of Agricultural and Food Chemistry 70:13049−61

Schwarz M, Hofmann G, Winterhalter P. 2004. Investigations on anthocyanins in wines from Vitis vinifera cv. pinotage: Factors influencing the formation of pinotin a and its correlation with wine age. Journal of Agricultural and Food Chemistry 52:498−504

Blanco-Vega D, Gómez-Alonso S, Hermosín-Gutiérrez I. 2014. Identification, content and distribution of anthocyanins and low molecular weight anthocyanin-derived pigments in Spanish commercial red wines. Food Chemistry 158:449−58

de Freitas V, Mateus N. 2011. Formation of pyranoanthocyanins in red wines: a new and diverse class of anthocyanin derivatives. Analytical and Bioanalytical Chemistry 401:1463−73

Catania A, Lerno L, Sari S, Fanzone M, Casassa F, et al. 2021. Impact of micro-oxygenation timing and rate of addition on color stabilization and chromatic characteristics of cabernet sauvignon wines. LWT 149:111776

He JR, Oliveira J, Silva AMS, Mateus N, De Freitas V. 2010. Oxovitisins: A new class of neutral pyranone-anthocyanin derivatives in red wines. Journal of Agricultural and Food Chemistry 58:8814−19

Zhang K, Zhang ZZ, Yuan L, Gao XT, Li Q. 2021. Difference and characteristics of anthocyanin from Cabernet Sauvignon and Merlot cultivated at five regions in Xinjiang. Food Science and Technology 41:72−80

Oliveira J, Azevedo J, Silva AMS, Teixeira N, Cruz L, et al. 2010. Pyranoanthocyanin Dimers: A New Family of Turquoise Blue Anthocyanin-Derived Pigments Found in Port Wine. Journal of Agricultural and Food Chemistry 58:5154−59

Gómez-Míguez M, González-Miret ML, Heredia FJ. 2007. Evolution of colour and anthocyanin composition of Syrah wines elaborated with pre-fermentative cold maceration. Journal of Food Engineering 79:271−78

Budić-Leto I, Mucalo A, Ljubenkov I, Zdunić G. 2018. Anthocyanin profile of wild grape Vitis vinifera in the eastern Adriatic region. Scientia Horticulturae 238:32−37

Lago-Vanzela ES, Procópio DP, Fontes EAF, Ramos AM, Stringheta PC, et al. 2014. Aging of red wines made from hybrid grape cv. BRS Violeta:Effects of accelerated aging conditions on phenolic composition, color and antioxidant activity. Food Research International 56:182−89

Guan L, Li JH, Fan PG, Li SH, Fang JB, et al. 2014. Regulation of Anthocyanin Biosynthesis in Tissues of a Teinturier Grape Cultivar under Sunlight Exclusion. American Journal of Enology and Viticulture 65:363−74

Tarara JM, Lee J, Spayd SE, Scagel CF. 2008. Berry temperature and solar radiation alter acylation, proportion, and concentration of anthocyanin in Merlot grapes. American Journal of Enology and Viticulture 59:235−47

Zou L, Zhong GY, Wu B, Yang Y, Li S, et al. 2019. Effects of sunlight on anthocyanin accumulation and associated co-expression gene networks in developing grape berries. Environmental and Experimental Botany 166:103811

Haselgrove L, Botting D, van Heeswijck R, Høj PB, Dry PR, et al. 2000. Canopy microclimate and berry composition: the effect of bunch exposure on the phenolic composition of Vitis vinifera L. cv. Shiraz grape berries. Australian Journal of Grape and Wine Research 6:141−49

Mori K, Goto-Yamamoto N, Kitayama M, Hashizume K. 2007. Loss of anthocyanins in red-wine grape under high temperature. Journal of Experimental Botany 58:1935−45

de Rosas I, Ponce MT, Malovini E, Deis L, Cavagnaro B, Cavagnaro P. 2017. Loss of anthocyanins and modification of the anthocyanin profiles in grape berries of Malbec and Bonarda grown under high temperature conditions. Plant Science 258:137−45

Liang NN, Zhu BQ, Han S, Wang JH, Pan QH, et al. 2014. Regional characteristics of anthocyanin and flavonol compounds from grapes of four Vitis vinifera varieties in five wine regions of China. Food Research International 64:264−74

Casassa LF, Larsen RC, Beaver CW, Mireles MS, Keller M, et al. 2013. Impact of extended maceration and Regulated Deficit Irrigation (RDI) in Cabernet Sauvignon wines: Characterization of proanthocyanidin distribution, anthocyanin extraction, and chromatic properties. Journal of Agricultural and Food Chemistry 61:6446−57

Gonçalves FJ, Fernandes PAR, Wessel DF, Cardoso SM, Rocha SM, et al. 2018. Interaction of wine mannoproteins and arabinogalactans with anthocyanins. Food Chemistry 243:1−10

Escott C, Del Fresno JM, Loira I, Morata A, Tesfaye W, et al. 2018. Formation of polymeric pigments in red wines through sequential fermentation of flavanol-enriched musts with non-Saccharomyces yeasts. Food Chemistry 239:975−83

Morata A, Escott C, Loira I, Del Fresno JM, González C, et al. 2019. Influence of Saccharomyces and non-Saccharomyces Yeasts in the formation of pyranoanthocyanins and polymeric pigments during red wine making. Molecules 24:4490

Li H, Guo A, Wang H. 2008. Mechanisms of oxidative browning of wine. Food Chemistry 108:1−13

Oliveira CM, Ferreira ACS, De Freitas V, Silva AMS. 2011. Oxidation mechanisms occurring in wines. Food Research International 44:1115−26

Shenoy VR. 1993. Anthocyanins - Prospective Food Colors. Current Science 64:575−79

Pérez-Magariño S, Sánchez-Iglesias M, Ortega-Heras M, González-Huerta C, González-Sanjosé ML. 2007. Colour stabilization of red wines by microoxygenation treatment before malolactic fermentation. Food Chemistry 101:881−93

Gambuti A, Picariello L, Forino M, Errichiello F, Guerriero A, et al. 2022. How the management of pH during winemaking affects acetaldehyde, polymeric pigments and color evolution of red wine. Applied Sciences-Basel 12:2555

Malaj N, De Simone BC, Quartarolo AD, Russo N. 2013. Spectrophotometric study of the copigmentation of malvidin 3-O-glucoside with p-coumaric, vanillic and syringic acids. Food Chemistry 141:3614−20

Zhao LY, Chen J, Wang ZQ, Shen RM, Cui N, et al. 2016. Direct acylation of cyanidin-3-glucoside with lauric acid in blueberry and its stability analysis. International Journal of Food Properties 19:1−12

Zhang PL, Liu S, Zhao ZG, You LJ, Harrison MD, et al. 2021. Enzymatic acylation of cyanidin-3-glucoside with fatty acid methyl esters improves stability and antioxidant activity. Food Chemistry 343:128482

Scharfetter J, Workmaster BA, Atucha A. 2019. Preveraison Leaf removal changes fruit zone microclimate and phenolics in cold climate interspecific hybrid grapes grown under cool climate conditions. American Journal of Enology and Viticulture 70:297−307

Jin X, Wu X, Liu X. 2017. Phenolic characteristics and antioxidant activity of Merlot and Cabernet Sauvignon wines increase with vineyard altitude in a high-altitude region. South African Journal of Enology and Viticulture 38:132−43

Di Stefano V, Scandurra S, Pagliaro A, Di Martino V, Melilli MG. 2020. Effect of Sunlight Exposure on Anthocyanin and Non-Anthocyanin Phenolic Levels in Pomegranate Juices by High Resolution Mass Spectrometry Approach. Foods 9:1161

Pérez-Álvarez EP, Martínez-Vidaurre JM, Garde-Cerdán T. 2019. Anthocyanin composition of grapes from three different soil types in cv. Tempranillo A.O.C Rioja vineyards. Journal of the Science of Food and Agriculture 99:4833−41

Yang B, He S, Liu Y, Liu B, Ju Y, et al. 2020. Transcriptomics integrated with metabolomics reveals the effect of regulated deficit irrigation on anthocyanin biosynthesis in Cabernet Sauvignon grape berries. Food Chemistry 314:126170

Cheng G, He YN, Yue TX, Wang J, Zhang ZW. 2014. Effects of Climatic Conditions and Soil Properties on Cabernet Sauvignon Berry Growth and Anthocyanin Profiles. Molecules 19:13683−703

Suriano S, Alba V, Tarricone L, Di Gennaro D. 2015. Maceration with stems contact fermentation: Effect on proanthocyanidins compounds and color in Primitivo red wines. Food Chemistry 177:382−89

Río Segade S, Pace C, Torchio F, Giacosa S, Gerbi V, et al. 2015. Impact of maceration enzymes on skin softening and relationship with anthocyanin extraction in wine grapes with different anthocyanin profiles. Food Research International 71:50−57

Fan L, Wang Y, Xie P, Zhang L, Li Y, et al. 2019. Copigmentation effects of phenolics on color enhancement and stability of blackberry wine residue anthocyanins: Chromaticity, kinetics and structural simulation. Food Chemistry 275:299−308

You Y, Li N, Han X, Guo J, Zhao Y, et al. 2019. The effects of six phenolic acids and tannic acid on colour stability and the anthocyanin content of mulberry juice during refrigerated storage. International Journal of Food Science and Technology 54:2141−50

Gordillo B, Rivero FJ, Jara-Palacios MJ, González-Miret ML, Heredia FJ. 2021. Impact of a double post-fermentative maceration with ripe and overripe seeds on the phenolic composition and color stability of Syrah red wines from warm climate. Food Chemistry 346:128919

Baca-Bocanegra B, Nogales-Bueno J, Hernández-Hierro JM, Heredia FJ. 2020. Valorization of American Barrel-Shoot Wastes: Effect of Post Fermentative Addition and Readdition on Phenolic Composition and Chromatic Quality of Syrah Red Wines. Molecules 25:774

Bimpilas A, Panagopoulou M, Tsimogiannis D, Oreopoulou V. 2016. Anthocyanin copigmentation and color of wine: The effect of naturally obtained hydroxycinnamic acids as cofactors. Food Chemistry 197:39−46

Liu S, Li S, Lin G, Markkinen N, Yang H, et al. 2019. Anthocyanin copigmentation and color attributes of bog bilberry syrup wine during bottle aging: Effect of tannic acid and gallic acid extracted from Chinese gallnut. Journal of Food Processing and Preservation 43:e14041

Rivero FJ, Jara-Palacios MJ, Gordillo B, Heredia FJ, González-Miret ML. 2019. Impact of a post-fermentative maceration with overripe seeds on the color stability of red wines. Food Chemistry 272:329−36

Zhao X, He F, Zhang XK, Shi Y, Duan CQ. 2022. Impact of three phenolic copigments on the stability and color evolution of five basic anthocyanins in model wine systems. Food Chemistry 375:131670

Rinaldi A, Coppola M, Moio L. 2019. Aging of Aglianico and Sangiovese wine on mannoproteins: Effect on astringency and colour. Lwt-Food Science and Technology 105:233−41

Escribano-Viana R, Portu J, Garijo P, Lopez R, Santamaria P, et al. 2019. Effect of the Sequential Inoculation of Non-Saccharomyces/Saccharomyces on the Anthocyans and Stilbenes Composition of Tempranillo Wines. Frontiers in Microbiology 10:773

Bozic JT, Butinar L, Albreht A, Vovk I, Korte D, Vodopivec BM. 2020. The impact of Saccharomyces and non-Saccharomyces yeasts on wine colour: A laboratory study of vinylphenolic pyranoanthocyanin formation and anthocyanin cell wall adsorption. LWT 123:109072

Topić Božič J, Ćurko N, Kovačević Ganić K, Butinar L, Albreht A, et al. 2020. Synthesis of pyranoanthocyanins from Pinot Noir grape skin extract using fermentation with high pyranoanthocyanin producing yeasts and model wine storage as potential approaches in the production of stable natural food colorants. European Food Research and Technology 246:1141−52

Li SY, Zhao PR, Ling MQ, Qi MY, García-Estévez I, et al. 2020. Blending strategies for wine color modification I: Color improvement by blending wines of different phenolic profiles testified under extreme oxygen exposures. Food Research International 130:108885

Heras-Roger J, Alonso-Alonso O, Gallo-Montesdeoca A, Díaz-Romero C, Darias-Martín J. 2016. Influence of copigmentation and phenolic composition on wine color. Journal of Food Science and Technology-Mysore 53:2540−47

Escudero-Gilete ML, González-Miret ML, Heredia FJ. 2010. Implications of blending wines on the relationships between the colour and the anthocyanic composition. Food Research International 43:745−52

Del Alamo Sanza M, Nevares Domínguez I. 2006. Wine aging in bottle from artificial systems (staves and chips) and oak woods - Anthocyanin composition. Analytica Chimica Acta 563:255−63

Martínez-Gil A, Del Alamo-Sanza M, Nevares I. 2022. Evolution of red wine in oak barrels with different oxygen transmission rates. Phenolic compounds and colour. LWT 158:113133

Gómez-Plaza E, Cano-López M. 2011. A review on micro-oxygenation of red wines: Claims, benefits and the underlying chemistry. Food Chemistry 125:1131−40

Cano-López M, López-Roca JM, Pardo-Minguez F, Gómez Plaza E. 2010. Oak barrel maturation vs. micro-oxygenation:Effect on the formation of anthocyanin-derived pigments and wine colour. Food Chemistry 119:191−95

Oberholster A, Elmendorf BL, Lerno LA, King ES, Heymann H, et al. 2015. Barrel maturation, oak alternatives and micro-oxygenation: Influence on red wine aging and quality. Food Chemistry 173:1250−58

Lisanti MT, Capuano R, Moio L, Gambuti A. 2021. Wood powders of different botanical origin as an alternative to barrel aging for red wine. European Food Research and Technology 247:2309−20

Nevares I, del Alamo-Sanza M. 2021. Characterization of the oxygen transmission rate of new-ancient natural materials for wine maturation containers. Foods 10:140

Maioli F, Picchi M, Guerrini L, Parenti A, Domizio P, et al. 2022. Monitoring of Sangiovese red wine chemical and sensory parameters along one-year aging in different tank materials and glass bottle. ACS Food Science & Technology 2:221−39

Cano-López M, Pardo-Mínguez F, Schmauch G, Saucier C, Teissedre PL, et al. 2008. Effect of micro-oxygenation on color and anthocyanin-related compounds of wines with different phenolic contents. Journal of Agricultural and Food Chemistry 56:5932−41

Panprivech S, Lerno LA, Brenneman CA, Block DE, Oberholster A. 2015. Investigating the effect of cold soak duration on phenolic extraction during Cabernet Sauvignon fermentation. Molecules 20:7974−89

Cejudo-Bastante MJ, Gordillo B, Hernanz D, Escudero-Gilete ML, González-Miret ML, et al. 2014. Effect of the time of cold maceration on the evolution of phenolic compounds and colour of Syrah wines elaborated in warm climate. International Journal of Food Science and Technology 49:1886−92

Hellström J, Mattila P, Karjalainen R. 2013. Stability of anthocyanins in berry juices stored at different temperatures. Journal of Food Composition and Analysis 31:12−19

Gómez-Plaza E, Gil-Muñoz R, López-Roca JM, Martínez A. 2000. Color and phenolic compounds of a young red wine. Influence of wine-making techniques, storage temperature, and length of storage time. Journal of Agricultural and Food Chemistry 48:736−41

Arapitsas P, Speri G, Angeli A, Perenzoni D, Mattivi F. 2014. The influence of storage on the "chemical age" of red wines. Metabolomics 10:816−32

Piffaut B, Kader F, Girardin M, Metche M. 1994. Comparative degradation pathways of malvidin 3,5-diglucoside after enzymatic and thermal treatments. Food Chemistry 50:115−20

Giuffrida de Esteban ML, Ubeda C, Heredia FJ, Catania AA, Assof MV, et al. 2019. Impact of closure type and storage temperature on chemical and sensory composition of Malbec wines (Mendoza, Argentina) during aging in bottle. Food Research International 125:108553

Ivanišević D, Kalajdžić M, Drenjančević M, Puškaš V, Korać N. 2020. The impact of cluster thinning and leaf removal timing on the grape quality and concentration of monomeric anthocyanins in Cabernet-Sauvignon and Probus (Vitis vinifera L.) wines. Oeno One 54:63−74

Chorti E, Guidoni S, Ferrandino A, Novello V. 2010. Effect of Different Cluster Sunlight Exposure Levels on Ripening and Anthocyanin Accumulation in Nebbiolo Grapes. American Journal of Enology and Viticulture 61:23−30

Yue X, Jing S, Ni X, Zhang K, Fang Y, et al. 2021. Anthocyanin and phenolic acids contents influence the color stability and antioxidant capacity of wine treated with mannoprotein. Frontiers in Nutrition691784

Rinaldo AR, Cavallini E, Jia Y, Moss SMA, McDavid DAJ, et al. 2015. A Grapevine Anthocyanin Acyltransferase, Transcriptionally Regulated by VvMYBA, Can Produce Most Acylated Anthocyanins Present in Grape Skins. Plant Physiology 169:1897−916