Microcapsules with condensates and liposomes composite membranes fabricated via soy protein simple coacervation

Coacervation is a common phenomenon in plant proteins which however has yet been well recognized. This study systematically investigated the properties of soy glycinin coacervates, explored the wetting behavior between the condensates and oil droplets in order to obtain microcapsules with core-shell...

Full description

Saved in:
Bibliographic Details
Published in:Food hydrocolloids 2025-03, Vol.160, p.110779, Article 110779
Main Authors: Chen, Nannan, Yang, Baoyan, Ren, Ranqi, Cai, Qiqi, Liu, Jiacheng, Cao, Hongkun, Wang, Yong
Format: Article
Language:English
Subjects:
Coacervation
Crosslinking
Liposome
Microcapsule
Soy protein
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Coacervation is a common phenomenon in plant proteins which however has yet been well recognized. This study systematically investigated the properties of soy glycinin coacervates, explored the wetting behavior between the condensates and oil droplets in order to obtain microcapsules with core-shell structure, and furthermore figured out the strategy to stabilize the condensate membranes. Fluidity of glycinin coacervates was characterized by viscosity and fluorescence recovery after photo bleaching which was highly dependent on solution parameters and intriguingly increased with prolonged time due to protein structure reorganization. Complete engulfment of oil droplets by coacervates leading to core-shell structure formation was achieved at salinity≥0.1M NaCl and pH ≥ 7 above room temperature. Core-shell structure could be preserved by membranization using liposome coating as it prevented the coalescence between coacervates. Condensate membranes were further hardened by a combination of physical and enzymatic crosslinking using calcium ions and transglutaminase respectively which enabled the microcapsules to survive in the gastric environment. This study is important as it paves way for fabricating well designed microcapsules based on the simple coacervation of plant proteins which are biocompatible and widely abundant. [Display omitted] •Solution parameters significantly influenced the properties of coacervates.•Core-shell structure formation occurred at [NaCl]≥0.1M, pH ≥ 7 above room temperature.•Liposome coating prevented the coalescence between coacervates.•Double crosslinking effectively enhanced stability of microcapsules.
ISSN:0268-005X
DOI:10.1016/j.foodhyd.2024.110779