Preparation of a nanocellulose/nanochitin coating on a poly(lactic acid) film for improved hydrolysis resistance

Growing concerns regarding plastic waste have prompted various attempts to replace plastic packaging films with biodegradable alternatives such as poly(lactic acid) (PLA). However, their low hydrolysis resistance owing to the presence of aliphatic polyesters limits the shelf life of biodegradable po...

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Bibliographic Details
Published in:International journal of biological macromolecules 2024-01, Vol.254 (Pt 2), p.127790-127790, Article 127790
Main Authors: Jeon, Hyeonyeol, Son, Joo Hee, Lee, Junhyeok, Park, Sung Bae, Ju, Sungbin, Oh, Dongyeop X, Koo, Jun Mo, Park, Jeyoung
Format: Article
Language:English
Subjects:
Food Packaging - methods
Hydrolysis
Polyesters
Water
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Summary:Growing concerns regarding plastic waste have prompted various attempts to replace plastic packaging films with biodegradable alternatives such as poly(lactic acid) (PLA). However, their low hydrolysis resistance owing to the presence of aliphatic polyesters limits the shelf life of biodegradable polymers. Hydrolysis leads to the deterioration of mechanical performance, which is a key disadvantage of biodegradable plastics. In this study, a layer-by-layer (LBL) assembly method was used for the dip-coating of biorenewable, biodegradable nanocellulose/nanochitin on the PLA surface. Additional crosslinking and compression of the coated nanofibers, each containing carboxylic acid and amine groups, respectively, were induced through electromagnetic microwave irradiation to protect the PLA film by improving hydrolysis resistance. The coatings were examined by morphological observations and water contact angle measurements. The LBL coatings of differently charged nanofibers of 10.6 μm were reduced to 40 % after microwave treatment, and the thickness does not vary after the hydrolysis experiment. Microwave irradiation increased the water contact angle owing to amide linkage formation, thereby preventing the peeling off of coating layers. Improved hydrolysis resistance inhibited the reduction in molecular weight and tensile strength. These findings could be used to develop sustainable and biodegradable plastic packaging films with a prolonged shelf life.
ISSN:0141-8130
1879-0003
DOI:10.1016/j.ijbiomac.2023.127790