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通过挤压加工对苹果渣进行改性:组成、聚合物结构及功能特性研究

Modification of Apple Pomace by Extrusion Processing: Studies on the Composition, Polymer Structures, and Functional Properties.

作者信息

Schmid Vera, Trabert Antje, Schäfer Judith, Bunzel Mirko, Karbstein Heike P, Emin M Azad

机构信息

Institute of Process Engineering in Life Sciences, Chair of Food Process Engineering, Karlsruhe Institute of Technology (KIT), 76131 Karlsruhe, Germany.

Institute of Applied Biosciences, Department of Food Chemistry and Phytochemistry, Karlsruhe Institute of Technology (KIT), 76131 Karlsruhe, Germany.

出版信息

Foods. 2020 Oct 1;9(10):1385. doi: 10.3390/foods9101385.

DOI:10.3390/foods9101385
PMID:33019534
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7601807/
Abstract

By-products of fruit and vegetable processing are an inexpensive and sustainable source of dietary fiber, potentially offering valuable functional properties such as water binding and thickening. Due to these favorable properties, they can be utilized to reformulate widely-consumed foods, e.g., bakery products or beverages. In this study, apple pomace was used as a model system to study whether extrusion technology affects food by-product functionality and thus has the potential to broaden the application of by-products in foods. The effect of the process parameters and the extent of thermo-mechanical treatment on the structural and functional properties of apple pomace were analyzed after extrusion trials using various screw speeds, water contents, and barrel temperatures. Compared to the raw material, apple pomace extruded at = 100 °C, = 700 min and = 17% showed an increased water solubility up to 33%. The water absorption increased from 5 to 19 Pa·s and the paste viscosity from 5 to 339 Pa·s by extrusion processing. Analyses of dietary fiber contents and fiber polysaccharide structures revealed that thermo-mechanical stress ( = 700 min, = 22%) increased the content of soluble dietary fiber from 12.5 to 16.7 g/100 g dry matter, and that the harshest conditions even enabled the formation of low-molecular-weight dietary fiber. Arabinans (as neutral rhamnogalacturonan I side chains) appeared to be most sensitive to thermo-mechanical stress, whereas xylans (i.e., a group of minor polysaccharides) were an example of a more stable fiber polysaccharide. Also, the degree of methylation of the pectic polysaccharides was strongly reduced from 50% to 15% when thermo-mechanical stress was applied. Imaging and pore size analysis showed that extrusion processing could disrupt the rigid cell wall macromolecular structure.

摘要

水果和蔬菜加工的副产品是一种廉价且可持续的膳食纤维来源,可能具有诸如水结合和增稠等有价值的功能特性。由于这些有利特性,它们可用于重新配方广泛消费的食品,例如烘焙产品或饮料。在本研究中,苹果渣被用作模型系统,以研究挤压技术是否会影响食品副产品的功能,从而有可能扩大副产品在食品中的应用。在使用各种螺杆转速、含水量和料筒温度进行挤压试验后,分析了工艺参数和热机械处理程度对苹果渣结构和功能特性的影响。与原料相比,在100℃、700分钟和17%含水量条件下挤压的苹果渣水溶解度提高了33%。通过挤压加工,吸水性从5增加到19帕·秒,糊粘度从5增加到339帕·秒。膳食纤维含量和纤维多糖结构分析表明,热机械应力(700分钟,22%)使可溶性膳食纤维含量从12.5克/100克干物质增加到16.7克/100克干物质,最苛刻的条件甚至能使低分子量膳食纤维形成。阿拉伯聚糖(作为中性鼠李半乳糖醛酸聚糖I侧链)似乎对热机械应力最敏感,而木聚糖(即一组次要多糖)是更稳定的纤维多糖的一个例子。此外,施加热机械应力时,果胶多糖的甲基化程度从50%大幅降至15%。成像和孔径分析表明,挤压加工会破坏刚性细胞壁大分子结构。

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