Scientia Agricultura Sinica ›› 2025, Vol. 58 ›› Issue (6): 1210-1222.doi: 10.3864/j.issn.0578-1752.2025.06.012

• FOOD SCIENCE AND ENGINEERING • Previous Articles     Next Articles

Effects of Bacterial Cellulose Combined pH Shifting Treatment on Gel Characteristics and Microstructure of Soy Protein Isolate

YAN SunHui(), LUO Cheng, CHEN YinJi, ZHUANG XinBo()   

  1. College of Food Science and Engineering, Nanjing University of Finance and Economics, Nanjing/Jiangsu Modern Grain Circulation and Safety Collaborative Innovation Center, Nanjing 210023
  • Received:2024-08-26 Accepted:2024-10-08 Online:2025-03-25 Published:2025-03-25
  • Contact: ZHUANG XinBo

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Abstract:

【Objective】 This study aimed to investigate the effects of bacterial cellulose combined pH shifting treatment on the gel properties and microstructure of soy protein isolate, and to elucidate the underlying mechanisms, so as to provide the theoretical support for the interactions between insoluble polysaccharides and protein molecules.【Method】 Soy protein isolate-bacterial cellulose composite systems were prepared with varying ratios of bacterial cellulose, with and without pH shifting treatment. Then, the effects of bacterial cellulose combined with pH shift treatment the gel properties, rheological characteristics, and microstructure of the soy protein isolate composite systems were study.【Result】 After the bacterial cellulose combined with pH shifting treatment, the particle size distribution analysis revealed a new composite peak around 4 145 nm, indicating an increase in the particle size of the soy protein isolate composite system. Additionally, as the ratio of bacterial cellulose increased, the particle size further rose to approximately 4 801 nm. The turbidity of the soy protein isolate with bacterial cellulose combined pH shifting treatment significantly increased, and this turbidity also rose with the higher addition of bacterial cellulose. Notably, the surface hydrophobicity of the group with bacterial cellulose combined pH shifting treatment was significantly enhanced (P<0.05). The visual appearance of the composite gel indicated that both the group with bacterial cellulose addition and the group with bacterial cellulose combined pH shifting treatment exhibited a smooth surface and good elasticity following the thermal process. The gel strength and rheological properties of the group with bacterial cellulose combined pH shifting treatment (15:1) showed significant improvement (P<0.05), with values increasing from 21.49 g and 0.93 Pa to 129.16 g and 556.2 Pa, respectively (P<0.05). Furthermore, the content of the β-sheet structure in the secondary structure increased significantly from 39.58% to 42.05% (P<0.05). Paraffin section results indicated that the bacterial cellulose physically filled the protein gel network, showing a distinct boundary with the soy protein isolate. In contrast, the gel network of the composite system treated with bacterial cellulose combined pH shifting treatment was uniformly distributed. Scanning electron microscopy (SEM) analysis showed that the soy protein isolate exhibited a porous structure with numerous aggregated formations, while the group with bacterial cellulose addition demonstrated extensive areas of accumulation. In the group bacterial cellulose combined pH shifting treatment, the filamentous bacterial cellulose was found to be embedded within the soy protein isolate, resulting in a tightly cross-linked protein structure. Laser confocal microscopy results indicated the presence of numerous pore structures in the control group, while the addition of bacterial cellulose did not reduce these pore structures and exhibited a phase-separated microstructure. However, after the pH shifting treatment, a tighter intertwined connection was formed between the soy protein isolate and bacterial cellulose, leading to a microstructure transformation from phase separation to phase uniformity, accompanied by a decrease in pore structure.【Conclusion】 The combination of bacterial cellulose with pH shift treatment could improve the gel properties of soybean protein isolate, and promote the phase separation structure to a uniform phase structure, which made the microstructure of the composite gel system more uniform and dense.

Key words: soy protein isolate, bacterial cellulose, pH shifting treatment, microstructure, gel properties

Table 1

Treatment methods of SPI in different experimental groups"

组别
Group		 大豆分离蛋白:细菌纤维素
SPI:BC		 pH 2偏移
pH 2 shifting treatment
T1
T2 30:1
T3 30:1 +
T4 15:1
T5 15:1 +

Fig. 1

Particle size distribution of SPI-BC composite system after different treatments"

Fig. 2

Turbidity of composite system solutions after different treatments"

Fig. 3

Effects of different treatment groups on surface hydrophobicity of soybean protein isolate"

Fig. 4

Appearance of the composite gel system formed by different treatment groups"

Fig. 5

Gel strength of the composite gel system formed by different treatment groups"

Fig. 6

Changes of storage modulus in the gel process in different treatment groups"

Fig. 7

Effects of different treatment groups on secondary structure of soybean protein isolate gels"

Fig. 8

Paraffin sections and SEM results of composite gels in different treatment groups"

Fig. 9

Confocal laser results of composite gels in different treatment groups"

Fig. 10

Effect of pH migration on soybean protein isolate and bacterial cellulose system"

[1]
SHEN R, LIN D H, LIU Z, ZHAI H L, YANG X B. Fabrication of bacterial cellulose nanofibers/soy protein isolate colloidal particles for the stabilization of high internal phase Pickering emulsions by anti-solvent precipitation and their application in the delivery of curcumin. Frontiers in Nutrition, 2021, 8: 734620.
[2]
PAN H Y, XU X M, TIAN Y Q, JIAO A Q, JIANG B, CHEN J, JIN Z Y. Impact of phase separation of soy protein isolate/sodium alginate co-blending mixtures on gelation dynamics and gels properties. Carbohydrate Polymers, 2015, 125: 169-179.

doi: 10.1016/j.carbpol.2015.02.030 pmid: 25857972
[3]
REDIGUIERI C F, DE FREITAS O, LETTINGA M P, TUINIER R. Thermodynamic incompatibility and complex formation in pectin/ caseinate mixtures. Biomacromolecules, 2007, 8(11): 3345-3354.
[4]
李向红. 大豆蛋白聚集体—多糖混合体系相行为及微观结构的研究[D]. 无锡: 江南大学, 2008.
LI X H. Phase behavior and microstructure of soy protein aggregate- polysaccharide mixtures[D]. Wuxi: Jiangnan University, 2008. (in Chinese)
[5]
崔冰. 卵白蛋白-CMC复合体系相行为及糖基化改性研究[D]. 武汉: 华中农业大学, 2012.
CUI B. Phase behavior and glycosylation of ovalbumin-CMC mixtures[D]. Wuhan: Huazhong Agricultural University, 2012. (in Chinese)
[6]
TURGEON S L, BEAULIEU M, SCHMITT C, SANCHEZ C. Protein- polysaccharide interactions: Phase-ordering kinetics, thermodynamic and structural aspects. Current Opinion in Colloid & Interface Science, 2003, 8(4/5): 401-414.
[7]
XIAO Q J, LI Z G, YANG J, HE Q, XI L, DU L F. Heat-induced unfolding of apo-CP43 studied by fluorescence spectroscopy and CD spectroscopy. Photosynthesis Research, 2015, 126(2): 427-435.
[8]
BRINK J, LANGTON M, STADING M, HERMANSSON A M. Simultaneous analysis of the structural and mechanical changes during large deformation of whey protein isolate/gelatin gels at the macro and micro levels. Food Hydrocolloids, 2007, 21(3): 409-419.
[9]
SCHMITT C, SANCHEZ C, DESPOND S, RENARD D, THOMAS F, HARDY J. Effect of protein aggregates on the complex coacervation between β-lactoglobulin and Acacia gum at pH 4.2. Food Hydrocolloids, 2000, 14(4): 403-413.
[10]
YUAN Y, WAN Z L, YIN S W, YANG X Q, QI J R, LIU G Q, ZHANG Y. Characterization of complexes of soy protein and chitosan heated at low pH. LWT-Food Science and Technology, 2013, 50(2): 657-664.
[11]
JIANG S S, MA Y Y, WANG Y H, WANG R, ZENG M Y. Effect of κ-carrageenan on the gelation properties of oyster protein. Food Chemistry, 2022, 382: 132329.
[12]
LIANG X P, MA C C, YAN X J, ZENG H H, MCCLEMENTS D J, LIU X B, LIU F G. Structure, rheology and functionality of whey protein emulsion gels: Effects of double cross-linking with transglutaminase and calcium ions. Food Hydrocolloids, 2020, 102: 105569.
[13]
KINSELLA J E. Functional properties of soy proteins. Journal of the American Oil Chemists’ Society, 1979, 56(3): 242-258.
[14]
KEERATI-U-RAI M, CORREDIG M. Heat-induced changes in oil-in-water emulsions stabilized with soy protein isolate. Food Hydrocolloids, 2009, 23(8): 2141-2148.
[15]
LIN D H, LOPEZ-SANCHEZ P, LI R, LI Z X. Production of bacterial cellulose by Gluconacetobacter hansenii CGMCC 3917 using only waste beer yeast as nutrient source. Bioresource Technology, 2014, 151: 113-119.
[16]
CAZÓN P, VÁZQUEZ M. Bacterial cellulose as a biodegradable food packaging material: A review. Food Hydrocolloids, 2021, 113: 106530.
[17]
SAVADKOOHI S, SHAMSI K, HOOGENKAMP H, JAVADI A, FARAHNAKY A. Mechanical and gelling properties of comminuted sausages containing chicken MDM. Journal of Food Engineering, 2013, 117(3): 255-262.
[18]
LAN Q Y, LI L, DONG H M, WU D T, CHEN H, LIN D R, QIN W, YANG W Y, VASANTHAN T, ZHANG Q. Effect of soybean soluble polysaccharide on the formation of glucono-δ-lactone-induced soybean protein isolate gel. Polymers, 2019, 11(12): 1997.
[19]
PAN X, FANG Y, WANG L L, SHI Y, XIE M H, XIA J, PEI F, LI P, XIONG W F, SHEN X C, HU Q H. Covalent interaction between rice protein hydrolysates and chlorogenic acid: Improving the stability of oil-in-water emulsions. Journal of Agricultural and Food Chemistry, 2019, 67(14): 4023-4030.

doi: 10.1021/acs.jafc.8b06898 pmid: 30901199
[20]
JIA N, WANG L T, SHAO J H, LIU D Y, KONG B H. Changes in the structural and gel properties of pork myofibrillar protein induced by catechin modification. Meat Science, 2017, 127: 45-50.

doi: S0309-1740(17)30052-9 pmid: 28119227
[21]
NASEEM F, AHMAD B, ASHRAF M T, KHAN R H. Molten globule-like folding intermediate of asialofetuin at acidic pH. Biochimica et Biophysica Acta (BBA)-Proteins and Proteomics, 2004, 1699(1/2): 191-199.
[22]
CHEN C, YOU L J, ABBASI A M, FU X, LIU R H. Optimization for ultrasound extraction of polysaccharides from mulberry fruits with antioxidant and hyperglycemic activity in vitro. Carbohydrate Polymers, 2015, 130: 122-132.
[23]
HAYAKAWA S, NAKAI S. Relationships of hydrophobicity and net charge to the solubility of milk and soy proteins. Journal of Food Science, 1985, 50(2): 486-491.
[24]
PRASANNA KUMARI N K, JAGANNADHAM M V. SDS induced molten globule state of heynein; a new thiol protease: Evidence of domains and their sequential unfolding. Colloids and Surfaces B: Biointerfaces, 2011, 82(2): 609-615.
[25]
李晓飞. 不同多糖对酸诱导酪蛋白凝胶特性的影响及凝胶机理研究[D]. 西安: 陕西师范大学, 2022.
LI X F. Effects of different polysaccharides on acid-induced casein gel properties and gel mechanism[D]. Xi’an: Shaanxi Normal University, 2022. (in Chinese)
[26]
CHEN D, CAMPANELLA O H. Limited enzymatic hydrolysis induced pea protein gelation at low protein concentration with less heat requirement. Food Hydrocolloids, 2022, 128: 107547.
[27]
GUO M H, LIU S C, ISMAIL M, FARID M M, JI H W, MAO W J, GAO J, LI C Y. Changes in the myosin secondary structure and shrimp surimi gel strength induced by dense phase carbon dioxide. Food Chemistry, 2017, 227: 219-226.

doi: S0308-8146(17)30050-X pmid: 28274425
[28]
HU Y, WANG Q, SUN F D, CHEN Q, XIA X F, LIU Q, KONG B H. Role of partial replacement of NaCl by KCl combined with other components on structure and gel properties of porcine myofibrillar protein. Meat Science, 2022, 190: 108832.
[29]
CORTEZ-TREJO M C, GAYTÁN-MARTÍNEZ M, REYES-VEGA M L, MENDOZA S. Protein-gum-based gels: Effect of gum addition on microstructure, rheological properties, and water retention capacity. Trends in Food Science & Technology, 2021, 116: 303-317.
[30]
DEVARAJ K B, KUMAR P R, PRAKASH V. Characterization of acid-induced molten globule like state of ficin. International Journal of Biological Macromolecules, 2009, 45(3): 248-254.

doi: 10.1016/j.ijbiomac.2009.05.008 pmid: 19482042
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