Scientia Agricultura Sinica ›› 2016, Vol. 49 ›› Issue (13): 2603-2611.doi: 10.3864/j.issn.0578-1752.2016.13.016

• STORAGE·FRESH-KEEPING·PROCESSING • Previous Articles     Next Articles

Gel Model and Mechanism of Low-Methoxyl Apple Pectin for Various pH

HAN Wan-you, DONG Gui-ru, QU Yu-ling MENG Yong-hong, GUO Yu-rong, DENG Hong   

  1. College of Food Engineering and Nutritional Science, Shaanxi Normal University, Xi’an 710100
  • Received:2016-01-08 Online:2016-07-01 Published:2016-07-01

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Abstract: 【Objective】The mathematical model of LM apple pectin gel strength which were prepared by citric acid - disodium hydrogen phosphate buffer solution were established with pH 1.78-6.62 and the mechanism of gelling was analyzed by data of rheology. The results of this study will provide a theoretical reference for the application of LMP in different pH environments. 【Method】Gel strength, rupture strength and rheological properties were measured by texture analyzer and rheometer, respectively. A model was established with Mate lab 10.0. According to the sol-gel transition point in graphs which was combined with storage shear modulus and loss shear modulus intersections in the graph, the pH range of gels could be determined. The mechanism of gels under different pH was analyzed on the basis of changes in storage shear modulus and loss shear modulus in the graph and the structure characteristics.【Result】The model of gel strength was followed by the polynomial law. In the range of pH 1.78-3.10, hydrophobic interactions between methoxyl ester groups and hydrogen bonds among undissociated carboxyl groups were formed which resulted in the sol to gel transition and gel strength to 21.19 g. When the pH of pectin solution was about 3.10, hydrophobic interactions between methoxyl ester groups and hydrogen bonds between undissociated carboxyl groups were formed. So that the elastic modulus increased significantly, the gel strength was about 21.00 g. In this pH range, although the pectin charge density was low, Ca2+ was still promoted the gel. However, the dissociation of carboxyl anion concentration could not reach the optimal amount of electronegativity carboxyl to form a stable “egg box”, gels were not so stable. In the range of pH 3.10-4.20, Calcium Bridge were formed between galacturonic acid residues and Ca2 +, which made gel tend to be stable and gel strength near to 22.00 g. In the range of pH 4.20-6.62, the electrostatic repulsion was predominant between pectin chains, which generated pectin gradually depolymerization because of free dissociated -COO- reached a maximum.【Conclusion】In the pH range of 1.78-6.30, LMP could form gels. When pH was in the range of 1.78-3.10, the pectin could be used at strongly acidic conditions and suitable for higher acidity of foods and medicines. When pH was in the range of 3.10-4.20, the stable gels could meet the food requirements of higher food gel texture. The results of this study have practical significance for the application of low methyl ester pectin in food with different pH ranges.

Key words: LM-apple pectin, pH, gel strength, rheological, elastic modulus, mathematical model, gel mechanism

[1]    Lutz R, Aserin A, Wicker L, GARTI N. Structure and physical properties of pectins with block-wise distribution of carboxylic acid groups. Food Hydrocolloids, 2009, 23(3): 786-794.
[2]    韩健, 王永春, 黄震. 果胶凝胶在生物医学应用上的研究进展. 农产品加工, 2015, 378(2): 58-60.
Han J, Wang Y C, Huang Z. Advances in biomedical applications of pectin gels. Agricultural Products Processing, 2015, 378(2): 58-60. (in Chinese)
[3]    奚苗苗, 张筱芳, 张三奇. 果胶及果胶钙在结肠靶向给药系统中的应用. 西北药学杂志, 2005(4): 183-184.
XI M M, Zhang X F, Zhang S Q. Application of pectin and pectin calcium for colon-targeting drug delivery system pectin-based systems drug delivery system. Northwest Pharmaceutical Journal, 2005(4): 183-184. (in Chinese)
[4]    陈娜. 天然食用胶体-果胶应用及发展前景. 食品安全导刊, 2013(9): 46-47.
Chen N. Application and development of natural edible colloid pectin. China Food Safety Magazine, 2013(9): 46-47. (in Chinese)
[5]    刘文, 董赛丽, 梁金亚. 果胶的性质、功能及其应用. 三门峡职业技术学院学报, 2008(2): 118-121.
LIU W, DONG S L, LIANG J Y. The nature, function and application of pectin. Journal of Sanmenxia Polytechnic, 2008(2): 118-121. (in Chinese)
[6]    Ngouémazong D E, Jolie R P, Cardinaels R, FRAEYE I, LOEY A, MOLDENAERS P, HENDRICKX M. Stiffness of Ca2+-pectin gels: combined effects of degree and pattern of methylesterification for various Ca2+ concentrations. Carbohydrate Research, 2012, 348(3): 69-76.
[7]    NGOUEMAZONG D E, NKEMAMIN N F, CARDINAELS R, JOLIE R P, FRAEYE I, LOEY A, MOLDEBAERS P, HENDRICKX M. Rheological properties of Ca2+-gels of partially methylesterified polygalacturonic acid: Effect of “mixed” patterns of methylesterification. Carbohydrate Polymers, 2012, 88(1): 37-45.
[8]    NGOUEMAZONG D E, TENGWEH F F, FRAEYE I, DUVETTER T, CARDINAELS R, LOEY A V, MOLDENAERS P, HENDRICKX M. Effect of de-methylesterification on network development and nature of Ca2+-pectin gels: Towards understanding structure-function relations of pectin. Food Hydrocolloids, 2012, 26(1): 89-98.
[9]    ALBA K, KASAPIS S, KONTOGIORGOS V, DUVETTER T, CARDINAELS R, LOEY A V, MOLDENAERS P, HENDRICKX M. Influence of pH on mechanical relaxations in high solids LM-pectin preparations. Carbohydrate Polymers, 2015, 127: 182-188.
[10]   NGOUEMAZONG D E, TENGWEH F F, FRAEYE I, DUVETTER  T, CARDINAELS R, LOEY A V, MOLDENAERS P, HENDRICKX M. Effect of de-methylesterification on network development and nature of Ca2+-pectin gels: Towards understanding structure-function relations of pectin. Food Hydrocolloids, 2012, 26(1): 89-98.
[11]   CAPEL F, NICOLAI T, DURAND D, BOULENGUER P, LANGENDORFF V. Calcium and acid induced gelation of (amidated) low methoxyl pectin. Food Hydrocolloids, 2006, 20(6): 901-907.
[12]   BEHROUZIAN F, RAZAVIS S M A, KARAZHIYAN H. Intrinsic viscosity of cress (Lepidium sativum) seed gum: effect of salts and sugars. Food Hydrocolloids, 2014, 35: 100-105.
[13]   陈豆弟, 张露, 代红灵. 果胶提取工艺的研究进展. 饮料工业, 2012, 15(2): 8-11.
CHEN D D, ZHANG L, DAI H L. Advances in study on pectin extraction processes, Beverage industry, 2012, 15(2): 8-11. (in Chinese)
[14]   李永春, 赵美荣, 朱月. 低酯果胶制备方法的研究进展. 赤峰学院学报(自然科学版), 2012, 28(20): 104-107.
LI Y C, ZHAO M R, ZHU Y. Advances in preparation of low ester pectin. Journal of Chifeng University (Natural Science Edition), 2012, 28(20): 104-107. (in Chinese)
[15]   戴余军, 丁文, 石会军. 纤维素酶提取柑桔皮果胶工艺条件的研究. 河北农业大学学报, 2011, 34(2): 71-74.
DAI Y J, DING W, SHI H J. Research on the process of extraction pectin from orange peel using the cellulose. Journal of Agricultural University of Hebei, 2011, 34(2): 71-74. (in Chinese)
[16]   PTICHKINA N M, MARKINA O A, RUMYANTSEVA G N. Pectin extraction from pumpkin with the aid of microbial enzymes. Food Hydrocolloids, 2008, 22(1): 192-195.
[17]   WANG S, CHEN F, WU J, WANG Z F, LIAO X J, HU X S. Optimization of pectin extraction assisted by microwave from apple pomace using response surface methodology. Journal of Food Engineering, 2007, 78(2): 693-700.
[18]   余先纯. 纯响应面优化微波加热法提取橘皮果胶. 食品研究与开发, 2012, 33(3): 64-67.
YU X C. Response surface optimize on extraction of pectin from orange peels with microwave heating. Food Research and Development, 2012, 33(3): 64-67. (in Chinese)
[19]   邓刚, 焦聪聪, 许杭琳. 超声辅助提取佛手废渣果胶的工艺优化. 食品科学, 2011, 32(14): 103-107.
DENG G, JIAO C C, XU H L. Optimization of ultrasonic-assisted extraction for pectin from bergamot residue. Food Science, 2011, 32(14): 103-107. (in Chinese)
[20]   汪海波. 低酯果胶的凝胶质构性能研究. 食品科学, 2006, 27(12): 123-129.
WANG H B. Study on gelling characteristics to low methoxyl pectin. Food Science, 2006, 27(12): 123-129. (in Chinese)
[21]   赵江. 低酯果胶凝胶形成条件的优化研究. 河南工业大学学报(自然科学版), 2009, 30(2): 8-11.
ZHAO J. Study on optimizing of gelatin forming conditions of low methoxyl pectin. Journal of Henan University of Technology (Natural Science Edition), 2009, 30(2): 8-11. (in Chinese)
[22]   International Organization for Standerdization. Adhesives-animal glues- methods for sampling and testing[S]. ISO 9665: 1998.
[23]   WINTER H H, MOURS M. Rheology of polymers near liquid-solid transitions. Springer Berlin Heidelberg, 1997(134): 165-234.
[24]   CHAMBON F, WINTER H H. Stopping of crosslinking reaction in a PDMS polymer at the gel point. Polymer Bulletin, 1985, 13(6): 499-503.
[25]   GILSENAN P M, RICHARDSON R K, MORRIS E R. Thermally reversible acid-induced gelation of low-methoxy pectin. Carbohydrate Polymers, 2000, 41(4): 339-349.
[26]   FRAEYE I, COLLE I, VANDEVENNE E, DUVETTER T, BUGGENHOUT S V, MOLDENAERS P, LOEY A V, HENDRICKX M. Influence of pectin structure on texture of pectin-calcium gels. Innovative Food Science & Emerging Technologies, 2010, 11(2): 401-409.
[27]   MORRIS E R, POWELL D A, GIDLEY M J, REES D A. Conformations and interactions of pectins: I. Polymorphism between gel and solid states of calcium polygalacturonate. Journal of molecular biology, 1982, 155(4): 507-516.
[28]   CARDENAS A, GOYCOOLEA F M, RINAUDO M. On the gelling behaviour of ‘nopal’ (Opuntia ficus indica) low methoxyl pectin. Carbohydrate Polymers, 2008, 73(2): 212-222.
[29]   STEPHEN A M. Food polysaccharides and their applications. Food Science & Technology, 1995, 1(2): 25-85.
[30]   王卫平. 食品改良剂: 亲水胶体的性质及应用(之五)-果胶.食品与发酵工业, 1996(4): 81-84.
WANG W P. The properties and applications of hydrophilic colloid (five) – pectin. Food and Fermentation Industry, 1996(4): 81-84. (in Chinese)
[31]   LOOTENS D, CAPEL F, DURAND D, NICOLAI T, BOULENGUER P, LANGENDORFF V. Influence of pH, Ca concentration, temperature and amidation on the gelation of low methoxyl pectin. Food Hydrocolloids, 2003, 17(3): 237-244.
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