Ultrasound pre-fractured casein and in-situ formation of high internal phase emulsions

•Ultrasound could loose the casein flocs to in-situ prepare Pickering HIPEs.•Edible oil stability was increased with the increase of ultrasonic power.•HIPEs mechanical strength was firm with the increase of ultrasonic power.•HIPEs viscosity was increased with the increase of ultrasonic power. Tradit...

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Bibliographic Details
Published in:Ultrasonics sonochemistry 2020-06, Vol.64, p.104916-104916, Article 104916
Main Authors: Bi, An-Qi, Xu, Xian-Bing, Guo, Yu, Du, Ming, Yu, Cui-Ping, Wu, Chao
Format: Article
Language:English
Subjects:
Casein
Caseins - chemistry
Emulsions
Food-grade
Isoelectric Point
Mechanical Phenomena
Pickering HIPEs
Rheology
Ultrasonic treatment
Ultrasonic Waves
Ultrasound
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Summary:•Ultrasound could loose the casein flocs to in-situ prepare Pickering HIPEs.•Edible oil stability was increased with the increase of ultrasonic power.•HIPEs mechanical strength was firm with the increase of ultrasonic power.•HIPEs viscosity was increased with the increase of ultrasonic power. Traditional preparation of protein particles is usually complex and tedious, which is a major issue in the development of Pickering high internal phase emulsions (HIPEs). In this study, a facile and in-situ method for the preparation of food-grade Pickering HIPEs was developed using ultrasound pre-fractured casein flocs. The ultrasonic-treated casein protein and resulting Pickering HIPEs were characterised using particle size distribution, confocal laser scanning microscopy (CLSM), cryo-SEM, and rheological measurement. The results indicated that pH values of casein and ultrasonic power level were key parameters for casein protein dispersion into nanoparticles to form o/w Pickering HIPEs. In optimal conditions, the hexagons of emulsion droplets were close together, and the emulsions formed with ultrasonic caseins exhibited gel-like behaviour. Additionally, ultrasonic microscale-sized caseins (about 25 μm) disappeared upon the use of high speed homogenisation during the formation of HIPEs, while the chemical distribution revealed by confocal laser scanning microscopy indicated that the dispersive nanoparticles from casein proteins were evidently absorbed on the interface of HIPEs (cryo-SEM). These findings prove that ultrasound is an effective tool to loosen casein flocs to induce the in-situ formation of stabilised Pickering HIPEs. Overall, this work provides a green and facile route to convert edible oil into a soft solid, which has great potential for applications in biomedical materials, 3D printing technology, and various cosmetics.
ISSN:1350-4177
1873-2828
DOI:10.1016/j.ultsonch.2019.104916