Physicochemical properties and structure of buckwheat flour modified by steam-treatment

IF 1.6 4区农林科学

International Journal of Food Engineering Pub Date : 2023-03-01 DOI:10.1515/ijfe-2022-0289

Bo-Hai Yang, Jiake Wang, Tong Yang, Yi-fu Zhang, Yuhe Wang, Siqi Qiang, Junjun Zhou, Shuhong Li, Ye Chen

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引用次数: 0

Abstract

Abstract The natural buckwheat flour exhibits poor processing behaviour due to its conservative structure and the lack of gluten protein, thereby limiting its use in the food industry. The replacement of chemical modification with sustainable, environmentally friendly steam treatment is, currently, technically feasible and promising for most chemical modification methods. The data showed that the steam-treated buckwheat flour degree of gelatinization increased to 99.3 g/100 g, and water absorption increased to 3.93 g/100 g. Also, particle size of the samples in the trial group was significantly larger compared to the control group. Scanning electron microscopy and infrared tests showed that not only did the steam treatment disrupt the granular structure of the buckwheat flour, but its proximity crystalline ordering structure Importantly, rheological behaviour tests showed that the steam-treated buckwheat gel exhibited a better viscoelasticity. Consequently, steam-treated pre-gelatinized buckwheat flour readily forms a tight network structure and provided important information for potential processing applications.

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蒸汽改性荞麦粉的理化性质及结构

摘要天然荞麦粉由于其结构保守和缺乏面筋蛋白而表现出较差的加工性能，从而限制了其在食品工业中的应用。目前，用可持续、环保的蒸汽处理取代化学改性在技术上是可行的，对大多数化学改性方法来说都很有前景。结果表明，经蒸汽处理的荞麦粉的糊化度提高到99.3 g/100 g、吸水率提高到3.93 g/100 g.此外，与对照组相比，试验组样品的粒径明显更大。扫描电子显微镜和红外测试表明，蒸汽处理不仅破坏了荞麦粉的颗粒结构，而且破坏了其接近结晶的有序结构。重要的是，流变行为测试表明，经蒸汽处理的荞麦凝胶表现出更好的粘弹性。因此，经过蒸汽处理的预糊化荞麦粉很容易形成紧密的网络结构，并为潜在的加工应用提供了重要信息。

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来源期刊

International Journal of Food Engineering 农林科学-食品科技

CiteScore

3.20

自引率

0.00%

发文量

审稿时长

3.8 months

期刊介绍： International Journal of Food Engineering is devoted to engineering disciplines related to processing foods. The areas of interest include heat, mass transfer and fluid flow in food processing; food microstructure development and characterization; application of artificial intelligence in food engineering research and in industry; food biotechnology; and mathematical modeling and software development for food processing purposes. Authors and editors come from top engineering programs around the world: the U.S., Canada, the U.K., and Western Europe, but also South America, Asia, Africa, and the Middle East.