Ovalbumin-chitosan complex coacervation: Phase behavior, thermodynamic and rheological properties

Xiong, Wenfei; Ren, Cong; Jin, Weiping; Tian, Jin; Wang, Yuntao; Shah, Bakht Ramin; Li, Jin; Li, Bin

doi:10.1016/j.foodhyd.2016.07.018

Cited by 93 publications

(41 citation statements)

References 39 publications

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“… 125 , 127 – 132 Interestingly, polymers in a complex coacervate may remain mobile, and rearrangement is possible. Many studies focus on the coacervate's phase behaviour 133 or rheological 134 or thermal 135 properties. The final phase's log P (and hydrophobicity in general) is not a major concern in complex coacervation, since the mechanism of phase separation is different and the ultimate goal of coacervation is not necessarily to increase hydrophobicity or modify solubility as in HIP.…”

Section: Bridging Polyelectrolyte Coacervation Polymer–surfactant Comentioning

confidence: 99%

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Hydrophobic ion pairing: encapsulating small molecules, peptides, and proteins into nanocarriers

2019

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Section: Bridging Polyelectrolyte Coacervation Polymer–surfactant Comentioning

confidence: 99%

“…For a more complete survey of polyelectrolyte coacervation, see ref [124][125][126][127][128][130][131][132][133][134][135][136][137][138][139][140][141]…”

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confidence: 99%

Hydrophobic ion pairing: encapsulating small molecules, peptides, and proteins into nanocarriers

2019

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“…The results of frequency sweeping (0.1-100 Hz) meant that the SP/GA complex coacervates exhibited the typical viscoelastic behavior, and displayed more elastic property at lower frequency region and more viscous property at higher frequency region. On the contrary, for 85-SP/GA, 95-SP/GA, and G/GA complex coacervates, G 0 was higher than G 00 in the whole frequency range, implying the formation of highly interconnected gel-like network structures, which was agreed with the rheological properties of ovalbumin/chitosan complex coacervates (Xiong, et al, 2016), bovine serum albumin (BSA)/pectin (Ru et al, 2012) and whey protein/pectin complex coacervates (Raei, Rafe, & Shahidi, 2018). In the frequency range of 0.1-100 Hz, G' for 85-SP/GA and 95-SP/GA complex coacervates were much higher than that for SP/GA complex coacervates, indicating the high intermolecular interactions between proteins and GA in 85-SP/GA and 95-SP/GA complex coacervates, leading to the formation of the tight structures (Wang, Lee, Wang, et al, 2007).…”

Section: Ph Effectmentioning

confidence: 60%

Comparison of rheological properties of different protein/gum arabic complex coacervates

Dong

Cui

2019

J Food Process Engineering

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This study mainly focused on the comparison of rheological properties of soy proteins (SP)/gum arabic (GA) complex coacervates and gelatin (G)/gum arabic (GA) complex coacervates. Frequency sweeping (0.1–100 Hz) results at 25°C showed that SP/GA coacervates storage modulus and loss modulus were crossed at a frequency of 30 Hz. According to the Doi‐Onuki model, it was confirmed that SP/GA complex coacervates were structured with a characteristic length scale (L) of 40 nm, which was much larger than others. It meant that the structure of SP/GA complex coacervates was less tight. Temperature sweeping (40–10°C) results illustrated that L of G/GA complex coacervates were decreased from 600 to 10 nm during the cooling process due to the formation of hydrogen bonds, while L of SP/GA complex coacervates were not changed greatly. Light microscopy observations revealed that the G/GA complex coacervates were more regular after cooling to 10°C. All the results indicated that protein types greatly influenced the structures of the complex coacervates. The results in this article will be useful for clarifying the reasons why different complex coacervates showed different morphologies and will provide theoretical support for rational use of protein/polysaccharide complex coacervates in food industry. Practical applications Complex coacervation between proteins and polysaccharides is a common phenomenon in the food processing. Understanding the interactions of proteins and polysaccharides is of importance not only in making cost‐efficient use of functional ingredients, but also in designing novel foods, controlling and improving structures of food ingredients and textural properties of fabricated foods. This study mainly focused on the rheological properties of soy proteins/gum arabic (SP/GA) complex coacervates and gelatin/gum arabic (G/GA) complex coacervates. The results indicated that protein types greatly influenced the structures of the complex coacervates. Structures of SP/GA coacervates were less tight than others. Characteristic length scales of G/GA coacervate significantly decreased during cooling process. The results in this paper will provide theoretical support for rational use of protein/polysaccharide complex coacervates in food industry.

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“…The storage modulus ( G ′) was higher than the loss modulus ( G ″) for all samples with different pH values; both the G ′ and G ″ increased with frequency and did not intersect, suggesting that a highly interconnected gel‐like network structure was formed (Nishinari, ). In previous studies, a gel‐like network structure was found between bovine serum albumin (BSA) and KC (Chai and ), between BSA and gum from whole flaxseed (Liu, Shim, Wang, & Reaney, ), and in an ovalbumin‐chitosan coacervate (Xiong et al., ). These data indicated that the KC‐HP coacervate behaved more like a viscoelastic solid (Kim & Yoo, ).…”

Section: Resultsmentioning

confidence: 98%

“…KC-HP coacervate samples were collected by centrifugation (8,000 rpm, 10 min) of KC-HP mixtures. Frequency sweeps were used to describe the viscoelastic behavior of KC-HP coacervates (storage modulus [G ], loss modulus [G ]; Xiong et al, 2016) after conducting strain sweep tests to determine the linear viscoelastic region (Liu, Shim, Shen, Wang, & Reaney, 2017). The apparent viscosity of the coacervate was evaluated using shear rate sweeps varied from 0 to 100 s −1 .…”

Section: Rheological Measurementmentioning

confidence: 99%

Effects of Mixing Ratio and pH on the Electrostatic Interactions of Hydrolyzed Alaska Pollock Protein and κ‐Carrageenan

Cui

Xue

et al. 2018

Journal of Food Science

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Ovalbumin-chitosan complex coacervation: Phase behavior, thermodynamic and rheological properties

Cited by 93 publications

References 39 publications

Hydrophobic ion pairing: encapsulating small molecules, peptides, and proteins into nanocarriers

Hydrophobic ion pairing: encapsulating small molecules, peptides, and proteins into nanocarriers

Comparison of rheological properties of different protein/gum arabic complex coacervates

Effects of Mixing Ratio and pH on the Electrostatic Interactions of Hydrolyzed Alaska Pollock Protein and κ‐Carrageenan

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