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柑橘残渣中不同果胶材料在薄膜生产中的评估

Evaluation of Different Pectic Materials Coming from Citrus Residues in the Production of Films.

作者信息

Umaña Mónica, Simal Susana, Dalmau Esperanza, Turchiuli Christelle, Chevigny Chloé

机构信息

Department of Chemistry, Universitat de les Illes Balears, 07011 Palma, Spain.

INRAE, AgroParisTech, UMR SayFood, Université Paris-Saclay, 91120 Palaiseau, France.

出版信息

Foods. 2024 Jul 5;13(13):2138. doi: 10.3390/foods13132138.

DOI:10.3390/foods13132138
PMID:38998643
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11241157/
Abstract

This article explores the use of citrus residues as a source of different pectic materials for packaging film production: a water-soluble orange residue extract (WSE) (5% pectin), semi-pure pectins extracted in citric acid (SP) (50% pectin), and commercial pure citrus pectins (CP). First, these materials were characterized in terms of chemical composition. Then, films were produced using them pure or mixed with chitosan or glycerol through solvent-casting. Finally, antioxidant activity, functional properties (e.g., mechanical and gas barrier properties), and visual appearance of the films were assessed. WSE films showed the highest antioxidant activity but the lowest mechanical strength with the highest elongation at break (EB) (54%); incorporating chitosan increased the films' strength (Young's modulus 35.5 times higher). SP films showed intermediate mechanical properties, reinforced by chitosan addition (Young's modulus 4.7 times higher); they showed an outstanding dry O barrier. CP films showed a similar O barrier to SP films and had the highest Young's modulus (~29 MPa), but their brittleness required glycerol for improved pliability, and chitosan addition compromised their surface regularity. Overall, the type of pectic material determined the film's properties, with less-refined pectins offering just as many benefits as pure commercial ones.

摘要

本文探讨了利用柑橘残渣作为包装薄膜生产中不同果胶材料的来源

水溶性橙渣提取物(WSE)(约含5%果胶)、在柠檬酸中提取的半纯果胶(SP)(约含50%果胶)以及商业纯柑橘果胶(CP)。首先,对这些材料进行了化学成分表征。然后,通过溶剂浇铸法将它们单独或与壳聚糖或甘油混合制成薄膜。最后,评估了薄膜的抗氧化活性、功能特性(如机械性能和气体阻隔性能)以及外观。WSE薄膜表现出最高的抗氧化活性,但机械强度最低,断裂伸长率(EB)最高(54%);加入壳聚糖可提高薄膜强度(杨氏模量提高35.5倍)。SP薄膜表现出中等机械性能,添加壳聚糖后强度增强(杨氏模量提高4.7倍);它们表现出出色的干燥氧气阻隔性。CP薄膜的氧气阻隔性与SP薄膜相似,杨氏模量最高(约29MPa),但其脆性需要添加甘油以提高柔韧性,添加壳聚糖会损害其表面平整度。总体而言,果胶材料的类型决定了薄膜的性能,未精制的果胶与纯商业果胶具有同样多的优势。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c116/11241157/27322cc2d0ee/foods-13-02138-g008.jpg
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