Cellulose nanofiber-multilayered fruit peel-mimetic gelatin hydrogel microcapsules for micropackaging of bioactive ingredients

Cellulose nanofiber-multilayered fruit peel-mimetic gelatin hydrogel microcapsules for micropackaging of bioactive ingredients

•A cellulose-multilayered fruit peel-mimetic microcapsule (FPMC) system is proposed as a new micropackaging technology.•Fruit peel biomimicry was accomplished by coating the gelatin core flesh with a cellulose-reinforced shell containing an antioxidant and an oil softener.•Tailored engineering of th...

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Bibliographic Details
Published in:Carbohydrate polymers Vol. 229; p. 115559
Main Authors: Seo, Mintae, Seo, Minjeong, Choi, Song-Ee, Shin, Kyounghee, Lee, Jun Bae, Yang, Dong-Yeon, Kim, Jin Woong
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-02-2020
Subjects:
Antioxidants - chemistry
Capsules - chemistry
Cellulose - chemistry
Cellulose nanofibers
Compressive Strength
Fruit - chemistry
Fruit peel-mimetic microcapsules
Gelatin - chemistry
Glutaral - chemistry
Hydrogels - chemistry
Layer-by-layer deposition
Micropackaging
Nanofibers - chemistry
Particle Size
Micropackaging
CNFs
C12NEs
GMPs
AFM
FPMCs
PSS
Layer-by-layer deposition
LbL
SEM
GAPMs
TEMPO
PDMAC
TEM
PEO-b-PCL
Fruit peel-mimetic microcapsules
Cellulose nanofibers
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Summary:•A cellulose-multilayered fruit peel-mimetic microcapsule (FPMC) system is proposed as a new micropackaging technology.•Fruit peel biomimicry was accomplished by coating the gelatin core flesh with a cellulose-reinforced shell containing an antioxidant and an oil softener.•Tailored engineering of the FPMC shell prevented generation of microcracks during drying, thus exhibiting improved antioxidation performance. We report a facile but robust approach to fabricate fruit peel-mimetic microcapsules (FPMCs) of which shell was structured by layering cellulose nanofibers (CNFs) with an antioxidant and a waxy compound on monodisperse gelatin microparticles using the layer-by-layer deposition. The thickness and moduli of the shell increased commonly depending on the number of CNF layers, indicating that the incorporation of CNFs made the shell layer rigid. We determined that the coating of the outermost FPMC layer with dodecane nanoemulsions softened the shell surface, thus preventing the generation of microcracks, which is essential for minimizing dehydration in the drying process. Furthermore, we also confirmed that the co-deposition of a phenolic compound, gallic acid, which is encapsulated in the polymeric micelles, with the shell layers allowed the FPMCs to exert antioxidant effects against the influx of oxygen from the atmosphere. These results highlight that our FPMC system could pave the way for the development of a micropackaging technology that enables encapsulation and stabilization of bioactive ingredients.
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ISSN:0144-8617
1879-1344
DOI:10.1016/j.carbpol.2019.115559