食品与发酵工业 >

2023 , Vol. 49 >Issue 16: 323 - 330

DOI: https://doi.org/10.13995/j.cnki.11-1802/ts.032631

综述与专题评论

云状颗粒对果汁风味影响的研究进展

  • 周佳 ,
  • 贾蒙 ,
  • 张晨 ,
  • 马亚琴
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  • (西南大学柑桔研究所,国家柑桔工程技术研究中心,重庆,400712)
第一作者:硕士研究生(马亚琴副研究员为通信作者,E-mail:maya211@163.com)

收稿日期: 2022-06-15

  修回日期: 2022-08-22

  网络出版日期: 2023-09-12

基金资助

国家现代农业柑橘产业技术体系 (CARS-26-06B)

收起

Research progress on effect of cloudy particles on flavor of juice

  • ZHOU Jia ,
  • JIA Meng ,
  • ZHANG Chen ,
  • MA Yaqin
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  • (Citrus Research Institute, Southwest University, National Citrus Engineering Research Center, Chongqing 400712, China)

Received date: 2022-06-15

  Revised date: 2022-08-22

  Online published: 2023-09-12

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摘要

香气成分作为评价果汁品质的重要指标,在加工过程中易受各种因素的影响。果汁中悬浮的细小颗粒被称为云状颗粒,其对于保持、提升果汁加工过程中天然的“初级”水果风味至关重要,而云状颗粒和挥发性物质间的相互作用亦强烈影响香气物质的释放。该文综述了云状颗粒的组成结构,果汁加工关键操作过程中云状颗粒与风味化合物作用规律,不同加工单元对云状颗粒以及风味的影响,云状颗粒与挥发性物质间的相互作用机制,并阐释了新型非热加工技术在保留和提升果汁香气方面的优势及机理,旨在通过拓展果汁中云状颗粒系统的研究,分析多酚、蛋白质与挥发性物质相互作用机制,探讨加工技术与云状颗粒系统的作用规律,以期推动水果资源的绿色加工和果汁产品的风味提升。但精准地检测各种因素对云状颗粒中风味物质的保留和释放的定量影响极具挑战,因此,为了提升果汁风味品质,期待更多有关果汁云状颗粒系统的深度研究。

关键词: 云状颗粒; 果汁; 风味; 加工; 作用机制

本文引用格式

周佳 , 贾蒙 , 张晨 , 马亚琴 . 云状颗粒对果汁风味影响的研究进展[J]. 食品与发酵工业, 2023 , 49(16) : 323 -330 . DOI: 10.13995/j.cnki.11-1802/ts.032631

Abstract

Aroma components, as an important index to evaluate the quality of fruit juice, are easily affected by various factors during the processing. The fine particles suspended in fruit juice are called cloudy particles, which are essential to maintain and improve the natural “primary” fruit flavor during juice processing. Whereas the interaction between cloudy particles and volatile substances also strongly affects the release of aroma substances. This paper summarized the composition and structure of cloudy particles, the interaction between cloudy particles and flavor compounds in the key operation for juice processing, the influence of different processing units on cloudy particles and flavor, and the interaction mechanism among cloudy particles and volatile substances. Meanwhile, the advantages and mechanisms of the new non-thermal processing technology in retaining and enhancing the aroma of fruit juice were explained. The purpose of this review was to expand the research on cloudy particle systems in fruit juice, analyze the interaction mechanism among polyphenols, proteins, and volatile substances, and explore the interaction law between processing technologies and cloudy particle systems to promote green processing of fruit resources and enhance the flavor of fruit juice products. However, it is very challenging to accurately detect the quantitative effects of various factors on the retention and release of flavor substances in the cloudy particles. Therefore, to improve the flavor quality of fruit juice, it will be looking forward to more in-depth studies on the cloudy particle system of fruit juice.

Key words: cloudy particles; juice; flavor; processing; interaction

参考文献

[1] CHENG C X, JIA M, GUI Y, et al. Comparison of the effects of novel processing technologies and conventional thermal pasteurisation on the nutritional quality and aroma of Mandarin (Citrus unshiu) juice[J]. Innovative Food Science & Emerging Technologies, 2020, 64:102425.
[2] 范刚, 乔宇, 姚晓琳, 等. 柑橘加工制品中香气物质的研究进展[J]. 中国农业科学, 2009, 42(12):4324-4332.
FAN G, QIAO Y, YAO X L, et al. Advances in research of aroma compounds of Citrus processing products[J]. Scientia Agricultura Sinica, 2009, 42(12):4324-4332.
[3] SCOTT W C, KEW T J, VELDHUIS M K. Composition of orange juice cloud[J]. Journal of Food Science, 1965, 30(5):833-837.
[4] YAMASAKI M, YASUI T, ARIMA K. Pectic enzymes in the clarification of apple juice: Part I. study on the clarification reaction in a simplified model[J]. Agricultural and Biological Chemistry, 1964, 28(11):779-787.
[5] KANNER J, BENSHALOM N, SHOMER I. Pectin-hesperidin interaction in a citrus cloud model syestem[J]. Lebensmittel-Wissenschaft Und-Technologie-Food Science and Technology, 1982, 15(6): 348-350.
[6] ROBERTS D D, ELMORE J S, LANGLEY K R, et al. Effects of sucrose, guar gum, and carboxymethylcellulose on the release of volatile flavor compounds under dynamic conditions[J]. Journal of Agricultural and Food Chemistry, 1996, 44(5):1321-1326.
[7] TIWARI B K, MUTHUKUMARAPPAN K, O'DONNELL C P, et al. Inactivation kinetics of pectin methylesterase and cloud retention in sonicated orange juice[J]. Innovative Food Science & Emerging Technologies, 2009, 10(2):166-171.
[8] CAO L Q, LU W, MATA A, et al. Egg-box model-based gelation of alginate and pectin: A review[J]. Carbohydrate Polymers, 2020, 242:116389.
[9] CHEN J, LIU W, LIU C M, et al. Pectin modifications: A review[J]. Critical Reviews in Food Science and Nutrition, 2015, 55(12):1684-1698.
[10] MITROPOULOU A, HATZIDIMITRIOU E, PARASKEVOPOULOU A. Aroma release of a model wine solution as influenced by the presence of non-volatile components. Effect of commercial tannin extracts, polysaccharides and artificial saliva[J]. Food Research International, 2011, 44(5):1561-1570.
[11] 沈雨思. 苹果浊汁云状颗粒果胶组分与特征风味化合物相互作用研究[D]. 锦州: 渤海大学, 2021.
SHEN Y S. Study on interaction between pectin components of cloudy particles and characteristic flavor compounds in cloudy apple juice[D]. Jinzhou: Bohai University, 2021.
[12] MERTZ C, CHEYNIER V, GÜNATA Z, et al. Analysis of phenolic compounds in two blackberry species (Rubus glaucus and Rubus adenotrichus) by high-performance liquid chromatography with diode array detection and electrospray ion trap mass spectrometry[J]. Journal of Agricultural and Food Chemistry, 2007, 55(21):8616-8624.
[13] DUFOUR C, SAUVAITRE I. Interactions between anthocyanins and aroma substances in a model system. Effect on the flavor of grape-derived beverages[J]. Journal of Agricultural and Food Chemistry, 2000, 48(5):1784-1788.
[14] FERREIRA V, JARAUTA I, LÓPEZ R, et al. Quantitative determination of sotolon, maltol and free furaneol in wine by solid-phase extraction and gas chromatography-ion-trap mass spectrometry[J]. Journal of Chromatography A, 2003, 1010(1):95-103.
[15] ZHU D S, SHEN Y S, WEI L W, et al. Effect of particle size on the stability and flavor of cloudy apple juice[J]. Food Chemistry, 2020, 328:126967.
[16] 魏立威. 过滤及均质对苹果浊汁云状颗粒稳定性的影响[D]. 锦州: 渤海大学, 2019.
WEI L W. Effects of filter and homogenization on the stability of particles in cloudy apple juice[D]. Jinzhou: Bohai University, 2019.
[17] FANG Z X, ZHANG M, BHANDARI B, et al. Microscopic structure of bayberry (Myrica rubra sieb. et zucc.) juice haze[J]. International Journal of Food Properties, 2009, 12(3):549-555.
[18] 易建勇, 毕金峰, 刘璇, 等. 果胶结构域精细结构研究进展[J]. 食品科学, 2020, 41(7):292-299.
YI J Y, BI J F, LIU X, et al. A review: Domain fine structure of pectic polysaccharides[J]. Food Science, 2020, 41(7):292-299.
[19] 陈西, 柳晓丹, 张同童, 等. 橙汁混浊稳定性的研究进展[J]. 食品工业科技, 2017, 38(8):384-389.
CHEN X, LIU X D, ZHANG T T, et al. Research progress on cloud stability of orange juice[J]. Science and Technology of Food Industry, 2017, 38(8):384-389.
[20] 赵光远, 李娜. 影响浊苹果汁混浊稳定性的因素[J]. 食品科技, 2007, 32(1):147-150.
ZHAO G Y, LI N. Factors in effecting the cloud stability of cloudy apple juice[J]. Food Science and Technology, 2007, 32(1):147-150.
[21] TIAN Y, SUN L J, YANG Y L, et al. Changes in the physicochemical properties, aromas and polyphenols of not from concentrate (NFC) apple juice during production[J]. CyTA-Journal of Food, 2018, 16(1):755-764.
[22] ABRAHAM K O, SASTRY L V L, NATARAJAN C P. Fruit flavours[J]. International Bottler and Packer, 1973, 47(7): 45-46; 48;50; 52; 54.
[23] LI M B, ZHANG W Z, ZHANG M Q, et al. Effect of centrifugal pre-treatment on flavor change of cloudy orange juice: Interaction between pectin and aroma release[J]. Food Chemistry, 2022, 374:131705.
[24] 张晨. 苹果汁加工中典型芳香成分的形态、变化及香气调控的研究[D].重庆: 西南大学, 2022.
ZHANG C. Study on bound and free aroma compounds and improvement of aroma in citrus juice based on enzymatic hydrolysis regulation[D].Chongqing: Southwest University, 2022.
[25] SUN X X, BALDWIN E A, PLOTTO A, et al. Effects of thermal processing and pulp filtration on physical, chemical and sensory properties of winter melon juice[J]. Journal of the Science of Food and Agriculture, 2017, 97(2):543-550.
[26] ZHU D S, KOU C C, SHEN Y S, et al. Effects of different processing steps on the flavor and colloidal properties of cloudy apple juice[J]. Journal of the Science of Food and Agriculture, 2021, 101(9):3819-3826.
[27] 孙爱东. 苹果汁加工中典型芳香成分的形态、变化及香气调控的研究[D]. 泰安: 山东农业大学, 2002.
SUN A D. Study on the form, variation and aroma regulation of typical aroma in apple juice processing[D]. Taian: Shandong Agricultural University, 2002.
[28] LIANG Z J, FANG Z X, PAI A, et al. Glycosidically bound aroma precursors in fruits: A comprehensive review[J]. Critical Reviews in Food Science and Nutrition, 2022, 62(1):215-243.
[29] WILKOWSKA A, POGORZELSKI E. Aroma enhancement of cherry juice and wine using exogenous glycosidases from mould, yeast and lactic acid bacteria[J]. Food Chemistry, 2017, 237:282-289.
[30] PEREZ-CACHO P R, ROUSEFF R. Processing and storage effects on orange juice aroma: A review[J]. Journal of Agricultural and Food Chemistry, 2008, 56(21):9785-9796.
[31] 王淑珍, 刘璇, 毕金峰, 等. 热处理对桃浊汁流变及果胶结构特性的影响[J]. 食品工业科技, 2017, 38(12):44-50.
WANG S Z, LIU X, BI J F, et al. Effects of heat treatment on the rheological properties and structure characteristics of pectin in cloudy peach juice[J]. Science and Technology of Food Industry, 2017, 38(12):44-50.
[32] WANG K, ARNTFIELD S D. Modification of interactions between selected volatile flavour compounds and salt-extracted pea protein isolates using chemical and enzymatic approaches[J]. Food Hydrocolloids, 2016, 61:567-577.
[33] JOUQUAND C, DUCRUET V, GIAMPAOLI P. Partition coefficients of aroma compounds in polysaccharide solutions by the phase ratio variation method[J]. Food Chemistry, 2004, 85(3):467-474.
[34] ESCOBEDO-AVELLANEDA Z, PÉREZ-SIMÓN I, LAVILLA-MARTÍN M, et al. Enzymatic and phytochemical stabilization of orange-strawberry-banana beverages by high hydrostatic pressure and mild heat[J]. Food Science and Technology International, 2017, 23(2):185-193.
[35] LIU F X, WANG Y T, LI R J, et al. Effects of high hydrostatic pressure and high temperature short time on antioxidant activity, antioxidant compounds and color of mango nectars[J]. Innovative Food Science & Emerging Technologies, 2014, 21:35-43.
[36] PAN X, WU J H, ZHANG W T, et al. Effects of sugar matrices on the release of key aroma compounds in fresh and high hydrostatic pressure processed Tainong mango juices[J]. Food Chemistry, 2021, 338:128117.
[37] ZHU D S, ZHANG Y Y, KOU C C, et al. Ultrasonic and other sterilization methods on nutrition and flavor of cloudy apple juice[J]. Ultrasonics Sonochemistry, 2022, 84:105975.
[38] 李楠楠. 高压脉冲电场技术对鲜榨椪柑汁的杀菌效果及品质影响的研究[D]. 重庆: 西南大学, 2018.
LI N N. Study on effect of pulsed electric fields on sterilization and quality in ponkan juice[D]. Chongqing: Southwest University, 2018.
[39] JIA M Y, HOWARD ZHANG Q, MIN D B. Pulsed electric field processing effects on flavor compounds and microorganisms of orange juice[J]. Food Chemistry, 1999, 65(4):445-451.
[40] TERTA M, BLEKAS G, PARASKEVOPOULOU A. Retention of selected aroma compounds by polysaccharide solutions: A thermodynamic and kinetic approach[J]. Food Hydrocolloids, 2006, 20(6):863-871.
[41] KINSELLA J E. Flavour perception and binding to food components[J]. Aroma Research, 1989, 55: 376-403.
[42] GHASEMI S, JAFARI S M, ASSADPOUR E, et al. Nanoencapsulation of d-limonene within nanocarriers produced by pectin-whey protein complexes[J]. Food Hydrocolloids, 2018, 77:152-162.
[43] KIM Y, KIM Y S, YOO S H, et al. Molecular differences of low methoxy pectins induced by pectin methyl esterase I: Effects on texture, release and perception of aroma in gel systems[J]. Food Chemistry, 2010, 123(2):451-455.
[44] KÜHN J, ZHU X Q, CONSIDINE T, et al. Binding of 2-nonanone and milk proteins in aqueous model systems[J]. Journal of Agricultural and Food Chemistry, 2007, 55(9):3599-3604.
[45] GUO J, HE Z Y, WU S F, et al. Binding of aroma compounds with soy protein isolate in aqueous model: Effect of preheat treatment of soy protein isolate[J]. Food Chemistry, 2019, 290:16-23.
[46] WANG K, ARNTFIELD S D. Binding of carbonyl flavours to canola, pea and wheat proteins using GC/MS approach[J]. Food Chemistry, 2014, 157:364-372.
[47] KING B M, SOLMS J. Interactions of volatile flavor compounds with propyl gallate and other phenols as compared with caffeine[J]. Journal of Agricultural and Food Chemistry, 1982, 30(5):838-840.
[48] DUFOUR C, BAYONOVE C L. Interactions between wine polyphenols and aroma substances. An insight at the molecular level[J]. Journal of Agricultural and Food Chemistry, 1999, 47(2):678-684.
[49] PETROZZIELLO M, ASPROUDI A, GUAITA M, et al. Influence of the matrix composition on the volatility and sensory perception of 4-ethylphenol and 4-ethylguaiacol in model wine solutions[J]. Food Chemistry, 2014, 149:197-202.
[50] GUO J, YUE T L, YUAN Y H. Impact of polyphenols on the headspace concentration of aroma compounds in apple cider[J]. Journal of the Science of Food and Agriculture, 2019, 99(4):1635-1642.
[51] BAINES Z V, MORRIS E R. Flavour/taste perception in thickened systems: The effect of guar gum above and below c*[J]. Food Hydrocolloids, 1987, 1(3):197-205.
[52] EVAGELIOU V, PAPASTAMOPOULOU K, FRANTZESKAKI D, et al. Retention of esters by gellan and pectin solutions or their mixtures[J]. Food Hydrocolloids, 2015, 51:54-59.
[53] EVAGELIOU V, PAPASTAMOPOULOU K, FRANTZESKAKI D, et al. Retention of esters by gellan and pectin solutions or their mixtures[J]. Food Hydrocolloids, 2015, 51:54-59.
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