Preparation of Composite Based on Soybean Protein Isolates and Chitosan

doi:10.11944/j.issn.1000-0518.2015.03.140240

Chinese Journal of Applied Chemistry ›› 2015, Vol. 32 ›› Issue (3): 327-334.DOI: 10.11944/j.issn.1000-0518.2015.03.140240

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Preparation of Composite Based on Soybean Protein Isolates and Chitosan

ZHAO Weigang, LU Zhenwu, LU Shengfang, HE Naipu^*

College of Chemical and Biological Engineering,Lanzhou Jiaotong University,Lanzhou 730070,China

Received:2014-07-10 Accepted:2014-11-06 Published:2015-03-02 Online:2015-03-02
Contact: Naipu HE
Supported by:
Supported by the National Natural Science Foundation of China(No.21164003), the Natural Science Foundation of Gansu Province(No.1212RJZA066, No.1308RJZA137)

Abstract

Abstract:

Electrostatic interactions between proteins and polysaccharides are a fundamental physico-chemical phenomenon in vivo. These interactions are believed to be the main driving force for the self-assembly. In addition, a proper understanding and control of this interaction should enable to design desired structures. Herein, the influences of mass ratios of chitosan(CS) to soybean protein isolates(SPI), pH, ion strength and temperature on the interactions between SPI and CS were investigated. The strength of electrostatic interactions between SPI and CS were mainly influenced by the pH values of solutions. The aggregation of SPI and CS occurred at pH varying from 5.5 to 6.6. At the low ion strength, a compact CS/SPI aggregates was formed, whereas, CS/SPI aggregates are dissociated at higher ion strength. As the heating induced denaturation of SPI, hydrophobic amino acid residues on the peptide chains are exposed to the solution, which results in an increase in hydrophobic interactions between CS and SPI. Furthermore, CS/SPI particles and bilayer film were prepared by adjusting the factors above. DLS reveals that nanoparticles are formed by the self-assembly between CS and SPI, and the hydrodynamic diameter is about 200 nm with uniform distribution. After the denaturation of SPI induced by heating, the hydrodynamic diameter is increased. Cross-linking by glutaraldehyde inducs a little decrease of hydrodynamic diameter. SEM results show that there are some cracks in the surface of chitosan monolayer film with thickness of ca 300 nm, and the cracks disappear after the formation of the bilayer film(CS/SPI) with thickness of ca 500 nm.

Key words: soybean protein isolates, chitosan, electrostatic interactions, nanoparticles, bilayer film

CLC Number:

ZHAO Weigang, LU Zhenwu, LU Shengfang, HE Naipu. Preparation of Composite Based on Soybean Protein Isolates and Chitosan[J]. Chinese Journal of Applied Chemistry, 2015, 32(3): 327-334.

References

[1]	Doublier J L,Garnier C,Renard D,et al.Protein-polysaccharide Interactions[J]. Curr Opin Colloid Interface Sci,2000,5(3/4):202-214.
[2]	Cooper C L,Dubin P L,Kayitmazer A B,et al.Polyelectrolyte Protein Complexes[J]. Curr Opin Colloid Interface Sci,2005,10(1/2):52-78.
[3]	Zhao X Y,Ao Q,Chen F S,et al.Effect of Reverse Micelle on Conformation of Soy Globulins:A Raman Study[J]. Food Chem,2009,116(1):176-182.
[4]	TIAN Kun,GUAN Juan,SHAO Zhengzhong,et al.Structural and Functional Study of Soybean Protein Isolation[J]. Prog Chem,2008,20(4):565-573(in Chinese ). 田琨,管娟,邵正中,等. 大豆分离蛋白结构与性能[J]. 化学进展,2008,20(4):565-573.
[5]	Xu J T,Ren J H,Ye L F,et al.Comparison of Laboratory and Industry Methods for the Separation of 7S and 11S Soy Proteins.Chemistry[M]//Keith R,Cadwallader,Sam K C C. Texture,and Flavor of Soy,ACS Sympos Ser,2010,1059:71-90.
[6]	Molina E,Papadopoulou A,Ledward D A. Emulsifying Properties of High Pressure Treated Soy Protein Isolate and 7S and 11S Globulins[J]. Food Hydrocolloids,2001,15(3):263-269.
[7]	Gonzalez de Mejia E,Dia V P. Chemistry and Biological Properties of Soybean Peptides and Proteins[M]. Texture,and Flavor of Soy,ACS Sympos Ser,2010,1059:133-154.
[8]	Sun X S,Wang D,Zhang L,et al.Morphology and Phase Separation of Hydrophobic Clusters of Soy Globular Protein Polymers[J]. Macromol Biosci,2008,8(4):295-303.
[9]	Adachi M,Chunying H,Utsumi S. Effects of Designed Sulfhydryl Groups and Disulfide Bonds into Soybean Proglycinin on its Structural Stability and Heat-induced Gelation[J]. J Agric Food Chem,2004,52(8):5717-5723.
[10]	Scilingo A A,Añòn M C. Calorimetric Study of Soybean Protein Isolates:Effect of Calcium and Thermal Treatments[J]. J Agric Food Chem,1996,44(12):3751-3756.
[11]	Alvarez P A,Ramaswamy H S,Ismail A A. High Pressure Gelation of Soy Proteins:Effect of Concentration, pH and Additives[J]. J Food Eng,2008,88(3):331-340.
[12]	Speroni F,Beaumal V,De Lamballerie M,et al.Gelation of Soybean Proteins Induced by Sequential High-pressure and Thermal Treatments[J]. Food Hydrocolloids,2009,23(5):1433-1442.
[13]	Van der Linden E,Venema P. Self-assembly and Aggregation of Proteins[J]. Curr Opin Colloid Interface Sci,2007,12(4/5):158-165.
[14]	Jaramillo P D,Roberts R F,Coupland J N. Effect of pH on the Properties of Soy Protein Pectin Complexes[J]. Food Res Int,2011,44(4):911-916.
[15]	Huang P H,Lu H T,Wang Y T,et al.Antioxidant Activity and Emulsion-Stabilizing Effect of Pectic Enzyme Treated Pectin in Soy Protein Isolate-Stabilized Oil/Water Emulsion[J]. J Agric Food Chem,2011,59(17):9623-9628.
[16]	Xiao J X,Yu H Y,Yang J. Microencapsulation of Sweet Orange Oil by Complex Coacervation with Soybean Protein Isolate/Gum Arabic[J]. Food Chem,2011,125(4):1267-1272.
[17]	Molina Ortiz S E,Puppo M C,Wagner J R. Relationship Between Structural Changes and Functional Properties of Soy Protein Isolates-carrageenan Systems[J]. Food Hydrocolloids,2004,18(6):1045-1053.
[18]	Turgeon S L,Schmitt C,Sanchez C. Protein Polysaccharide Complexes and Coacervates[J]. Curr Opin Colloid Interface Sci,2007,12(4/5):166-178.
[19]	HE Naipu,WANG Rongmin. Self-Assembly of Protein with Polymer[J]. Prog Chem,2012,24(1):94-100(in Chinese). 何乃普,王荣民. 蛋白质与高分子的自组装[J]. 化学进展,2012,24(1):94-100.
[20]	Kumar M N V R. A Review of Chitin and Chitosan Applications[J]. React Funct Polym,2000,46(1):1-27.
[21]	Rinaudo M. Chitin and Chitosan:Properties and Applications[J]. Prog Polym Sci,2006,31(7):603-632.
[22]	Pillai C K S,Paul W,Sharma C P. Chitin and Chitosan Polymers: Chemistry, Solubility and Fiber Formation[J]. Prog Polym Sci,2009,34(7):641-678.
[23]	George M, Abraham T E J. Polyionic Hydrocolloids for the Intestinal Delivery of Protein Drugs:Alginate and Chitosan-A Review[J]. Controlled Release,2006,114(1):1-14.
[24]	Kumar M N V R,Muzzarelli R A A,Muzzarelli C,et al. Chitosan Chemistry and Pharmaceutical Perspectives[J]. Chem Rev,2004,104(12):6017-6084.
[25]	Xu Y M,Du Y M. Effect of Molecular Structure of Chitosan on Protein Delivery Properties of Chitosan Nanoparticles[J]. Int J Pharm,2003,250(1):215-226.
[26]	HE Naipu,WANG Rongmin,SONG Pengfei,et al.Protein Polymer Conjugates[J]. Prog Chem,2010,22(12):2388-2396(in Chinese). 何乃普,王荣民,宋鹏飞,等. 蛋白质高分子结合体[J]. 化学进展,2010,22(12):2388-2396.
[27]	Jia W,Fang Z,Yue L,et al.Preparation and Characterization of Pullulan-chitosan and Pullulan-carboxymethyl Chitosan Blended Films[J]. Food Hydrocolloids,2013,30(1):82-91.
[28]	Attila E,Pavlath,William O. Edible Films and Coatings: Why, What, and How?[M]. Edible Films and Coatings for Food Applications. Springer Dordrecht Heidelberg London New York,2009:2-3.
[29]	Zhang X,Qi J R,Li K K,et al.Characterization of Soy β-Conglycinin-dextran Conjugate Prepared by Maillard Reaction in Crowded Liquid System[J]. Food Res Int,2012,49(2):648-654.
[30]	Neirynck N,Van M P,Bayarri G S,et al.Improved Emulsion Stabilizing Properties of Whey Protein Isolate by Conjugation with Pectins[J]. Food Hydrocolloids,2004,18(6):949-957.
[31]	Dickinson E,Izgi E. Foam Stabilization by Protein-Polysaccharide Complexes[J]. Food Res Int,1996,113(1/2):191-201.
[32]	Jung S,Roussel-Philippe C,Briggs J L,et al.Limited Hydrolysis of Soy Proteins with Endo-and Exoproteases[J]. J Am Oil Chem Soc,2004,81(10):953-960.
[33]	Lamsal B P,Jung S,Johnson L. A. Rheological Properties of Soy Protein Hydrolysates Obtained from Limited Enzymatic Hydrolysis[J]. Food Sci Technol,2007,40(7):1215-1223.
[34]	Ducel V,Richard J,Richard J,et al.Evidence and Characterization of Complex Coacervates Containing Plant Proteins:Application to the Microencapsulation of Oil Droplets[J]. Colloids Surf A,2004,232(2/3):239-249.
[35]	Seyrek E,Dubin P L,Tribet C,et al.Ionic Strength Dependence of Protein-polyelectrolyte Interactions[J]. Biomacromolecules,2003,4(2):273-282.
[36]	MA Dezhu,HE Pingsheng,XU Zhongde,et al.Structure and Properties of Polymers[M]. 2nd Ed. Beijing:Science Press,2000:544-545(in Chinese). 马德柱,何平笙,徐种德,等. 高聚物的结构与性能[M]. 第2版. 北京:科学出版社,2000:544-545.
[37]	Rangavajhyala N,Ghorpade V,Hanna M. Solubility and Molecular Properties of Heat-cured Soy Protein Films[J]. J Agric Food Chem,1997,45(11):4204-4208.

Preparation of Composite Based on Soybean Protein Isolates and Chitosan

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