Tomographical, rheological, and structural effects of soy protein concentrate in a gluten-free extruded noodle system

IF 2.8 3区 农林科学 Q2 FOOD SCIENCE & TECHNOLOGY
Geunhyuk Yang, Sungmin Jeong, Suyong Lee
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Abstract

Global interest in high-protein foods has been rapidly increasing and the gluten-free products are no exceptions. Gluten-free extruded noodles made from rice flour were thus fortified with soy protein concentrate (SPC) (0%, 15%, 30%, and 45% by weight), and the physicochemical properties of the noodles were characterized in terms of tomographical, rheological, and structural features. SPC-rice flour blends showed higher water absorption and swelling power at room temperature with increasing levels of SPC, which were reduced upon heating. The flour blends with high-levels of SPC also had lower pasting viscosities. Thermal analysis showed lower enthalpy values and higher temperatures derived from starch gelatinization. When the SPC-rice flour blends were applied to extruded gluten-free rice noodles, the noodles tomographically showed a dense and compact structure, that could be favorably correlated with their textural changes (increased hardness and reduced extensibility). FTIR analysis presented the structural changes of the noodles containing different levels of SPC by showing higher intensity of protein-related absorption peaks and lower starch peak intensity, which could be associated with the reduced cooking loss. Moreover, there existed two water components with different mobilities in the noodles whose spin–spin relaxation times had a tendency to increase with increasing SPC content. The results obtained from this study provided fundamental insights into the processing performance of protein-rich ingredients in gluten-free extruded noodles, probably promoting the development of a wider variety of protein-fortified gluten-free products.

Abstract Image

无麸质挤压面条系统中大豆浓缩蛋白的层析成像、流变学和结构效应。
全球对高蛋白食品的兴趣迅速增加,无麸质产品也不例外。因此,用大豆浓缩蛋白(SPC)(按重量计0%、15%、30%和45%)强化以米粉为原料的无麸质挤压面条,并从层析、流变和结构特征等方面对面条的理化性质进行了表征。随着SPC含量的增加,SPC米粉在室温下表现出更高的吸水性和溶胀力,而SPC含量在加热时降低。具有高SPC水平的面粉混合物也具有较低的糊化粘度。热分析显示,淀粉糊化产生的焓值较低,温度较高。当SPC米粉混合物应用于挤出的无麸质米粉时,面条的断层图显示出致密和紧凑的结构,这可能与它们的质地变化(硬度增加和延展性降低)密切相关。FTIR分析显示了含有不同SPC水平的面条的结构变化,显示出较高的蛋白质相关吸收峰强度和较低的淀粉峰强度,这可能与减少烹饪损失有关。此外,面条中存在两种具有不同迁移率的水组分,其自旋-自旋弛豫时间有随SPC含量增加而增加的趋势。这项研究的结果为无麸质挤压面条中富含蛋白质成分的加工性能提供了基本的见解,可能会促进更广泛的蛋白质强化无麸质产品的开发。
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来源期刊
Journal of texture studies
Journal of texture studies 工程技术-食品科技
CiteScore
6.30
自引率
9.40%
发文量
78
审稿时长
>24 weeks
期刊介绍: The Journal of Texture Studies is a fully peer-reviewed international journal specialized in the physics, physiology, and psychology of food oral processing, with an emphasis on the food texture and structure, sensory perception and mouth-feel, food oral behaviour, food liking and preference. The journal was first published in 1969 and has been the primary source for disseminating advances in knowledge on all of the sciences that relate to food texture. In recent years, Journal of Texture Studies has expanded its coverage to a much broader range of texture research and continues to publish high quality original and innovative experimental-based (including numerical analysis and simulation) research concerned with all aspects of eating and food preference. Journal of Texture Studies welcomes research articles, research notes, reviews, discussion papers, and communications from contributors of all relevant disciplines. Some key coverage areas/topics include (but not limited to): • Physical, mechanical, and micro-structural principles of food texture • Oral physiology • Psychology and brain responses of eating and food sensory • Food texture design and modification for specific consumers • In vitro and in vivo studies of eating and swallowing • Novel technologies and methodologies for the assessment of sensory properties • Simulation and numerical analysis of eating and swallowing
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