Effect of carboxymethyl cellulose binder on physical, thermal, and rheological properties of milk protein isolate/guar gum mixture powder

IF 5.3 2区农林科学 Q1 ENGINEERING, CHEMICAL Journal of Food Engineering Pub Date : 2024-09-11 DOI:10.1016/j.jfoodeng.2024.112317

Jun-Hwan Oh, Wonjae Lee, Juneha Bak, Byoungseung Yoo

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Abstract

This study examined the effect of fluidized-bed agglomeration with a carboxymethyl cellulose (CMC) binder on the physical, thermal, and rheological properties of agglomerated milk protein isolate (MPI)-guar gum (GG) mixtures (AMGs). The agglomeration process produced larger and more porous particles, improving solubility and powder flowability. An exothermic event followed by an endothermic event was observed in DSC thermograms. These thermal events tended to occur at a higher temperature with lower enthalpy values as the binder concentration increased. All samples exhibited shear-thinning behavior, with apparent viscosity at 100 s⁻¹ values (0.27–0.29 Pa s) for AMGs being lower than for non-agglomerated MPI-GG mixture (NAMG; 0.34 Pa s). Viscoelastic moduli values showed similar trends. Additionally, compared to NAMG, larger and more guar gum lumps occurred in the AMGs. These findings suggest that the agglomeration process with CMC promoted depletion interactions between the protein and polysaccharide components in the mixture system.

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羧甲基纤维素粘合剂对分离乳蛋白/瓜尔胶混合物粉末的物理、热和流变特性的影响

本研究考察了使用羧甲基纤维素（CMC）粘合剂进行流化床团聚对团聚牛奶蛋白分离物（MPI）-瓜尔胶（GG）混合物（AMGs）的物理、热和流变特性的影响。团聚过程产生了更大更多孔的颗粒，提高了溶解性和粉末流动性。在 DSC 热图中观察到一个放热事件，随后是一个内热事件。随着粘合剂浓度的增加，这些热事件往往发生在温度较高且焓值较低的地方。所有样品都表现出剪切稀化行为，AMG 在 100 s-1 时的表观粘度值（0.27-0.29 Pa s）低于非胶结 MPI-GG 混合物（NAMG；0.34 Pa s）。粘弹性模量值也呈现出类似的趋势。此外，与 NAMG 相比，AMG 中的瓜尔胶块更大、更多。这些发现表明，使用 CMC 的聚结过程促进了混合物体系中蛋白质和多糖成分之间的耗竭相互作用。

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来源期刊

Journal of Food Engineering 工程技术-工程：化工

CiteScore

11.80

自引率

5.50%

发文量

275

审稿时长

24 days

期刊介绍： The journal publishes original research and review papers on any subject at the interface between food and engineering, particularly those of relevance to industry, including: Engineering properties of foods, food physics and physical chemistry; processing, measurement, control, packaging, storage and distribution; engineering aspects of the design and production of novel foods and of food service and catering; design and operation of food processes, plant and equipment; economics of food engineering, including the economics of alternative processes. Accounts of food engineering achievements are of particular value.