Rheological, Thermal and Physicochemical Properties of Bioprocessed Flour From Cowpea, Sorghum and Orange Fleshed Sweet Potato

IF 2.7 3区 农林科学 Q3 ENGINEERING, CHEMICAL
Yusuf Olamide Kewuyemi, Chiemela Enyinnaya Chinma, Hema Kesa, Opeyemi Alabi, Eric Oscar Amonsou, Oluwafemi Ayodeji Adebo
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Abstract

This study investigated the rheological, physicochemical, and thermal properties of fermented and germinated whole reddish-brown cowpea, white sorghum and orange-fleshed sweet potato. Germination substantially reduced the pasting and rheological attributes of flour suspensions compared to the fermentation process. This study observed notable increases in the hot paste, setback, and final viscosities after the fermentation of cowpea and sorghum, indicating an improvement in the ease of cooking and greater retrogradation tendency of starch molecules. Among the fermented flours, sorghum had the highest hot paste viscosity (848 mPa s) and final viscosity (1451 mPa s). The mechanical fingerprint revealed a viscoelastic solid character, with G′ > G″ over the frequency range of 0–10 rad/s for all samples. Temperature sweep data showed a sharp increase in G′ at about 80°C, corresponding to the onset of starch gelatinization. Shear-thinning behavior was observed, except in germinated and raw sorghum flours, where molecular rearrangement resulted in an initial viscosity rise at a low share rate (< 20 s−1). Differential scanning calorimetric analysis revealed a marginal variation in the peak transition temperature of gelatinization (98°C–104°C for all flours except raw sorghum flour, 83.87°C). The fermented sweet potato flour indicated good flour particle flowability expressed as Carr's compressibility index (30.99) and the Hausner ratio (1.45); however, the available reducing sugars could have influenced its high percentage solubility (49.83%), thus impacting low pasting viscosities. The contrasting technological features suggest an avenue to intensify efforts in exploring composite bioprocessed flours for applications in novel foods.

Abstract Image

豇豆、高粱和橙肉甘薯生物加工面粉的流变、热和理化特性
本研究调查了发酵和发芽的红棕色豇豆、白高粱和橘皮甘薯全粉的流变学、物理化学和热学特性。与发酵过程相比,发芽过程大大降低了面粉悬浮液的糊化和流变特性。本研究观察到,豇豆和高粱发酵后的热糊度、后退度和最终粘度明显增加,这表明淀粉分子的易烹饪性和逆降解趋势得到了改善。在发酵面粉中,高粱的热糊粘度(848 mPa s)和最终粘度(1451 mPa s)最高。机械指纹显示出粘弹性固体特征,所有样品在 0-10 rad/s 频率范围内的 G′ > G″。温度扫描数据显示,G′在大约 80°C 时急剧上升,与淀粉糊化的开始时间相对应。除发芽高粱粉和生高粱粉外,均观察到了剪切稀化行为,在这两种情况下,分子重排导致初始粘度以较低的份额率(< 20 s-1)上升。差示扫描量热分析表明,糊化的峰值转变温度变化不大(除生高粱粉为 83.87°C 外,其他面粉均为 98°C-104°C)。用卡尔压缩指数(30.99)和豪斯纳比率(1.45)表示,发酵甘薯粉具有良好的面粉颗粒流动性;然而,可用还原糖可能会影响其较高的溶解度百分比(49.83%),从而影响较低的糊化粘度。这些对比鲜明的技术特征表明,应加大力度探索复合生物加工面粉在新型食品中的应用。
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来源期刊
Journal of Food Process Engineering
Journal of Food Process Engineering 工程技术-工程:化工
CiteScore
5.70
自引率
10.00%
发文量
259
审稿时长
2 months
期刊介绍: This international research journal focuses on the engineering aspects of post-production handling, storage, processing, packaging, and distribution of food. Read by researchers, food and chemical engineers, and industry experts, this is the only international journal specifically devoted to the engineering aspects of food processing. Co-Editors M. Elena Castell-Perez and Rosana Moreira, both of Texas A&M University, welcome papers covering the best original research on applications of engineering principles and concepts to food and food processes.
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