Physical characterization of freeze-dried foam prepared from Aloe vera gel and guar gum

V. Santacruz-Vázquez, C. Santacruz-Vázquez, Jordi Cortés
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引用次数: 7

Abstract

Background: Foams are colloidal dispersions of a gas suspended in a dispersing phase, which consisting of a semi-freeze-dried or viscous liquid phase. The physical properties of food foams are the result of the bubble characteristics and their spatial arrangement. Objectives: The aim of this work was to obtain foams of A. vera gel and guar gum and describe the changes in their physical properties and microstructure during freeze-drying using the fractal dimension concept and image analysis techniques. Methods: The porosity, density, and volume expansion factor of the fresh foams that were based on the A. vera foams were determined. The kinetics of foam texture, color, porosity and microstructure of the freeze-dried foams were obtained. The fractal texture dimension of surface (FDSDBC) and microstructure (FDESEM) of the foams were determined as indicators of structural changes after freeze-drying. The guar gum concentrations used to obtain the A. vera prefoam were expressed in w/w as F1 (control simple without gum), F2 (2%), F3 (4%) and F4 (6%). Results: We obtained stable freeze-dried foams of Aloe vera gel and guar gum. The porosity, density and volume expansion factor of the fresh and freeze-dried foams were affected by the addition of the guar gum. Changes in the topology of the freeze-dried foam surface during the drying process resulted in a high rugosity compared with the original smooth surface. The microstructure of the dried foam samples suggested a relationship between the gum concentration of the prefoam A. vera gel mixture and the physical properties before and after freeze-drying, such as an increase in the microstructural alterations and surface roughness during freeze-drying. The roughness of the freeze-dried foam surface, described by the FDSDBC represented the macroscopic physical changes of the samples and correlated with the changes in the foam microstructure, which were described by the fractal dimension of the Environmental Scanning Electron Microscopy ESEM microphotographs (FDESEM). Conclusions: The digital analysis of the structure and porosity of the freeze-dried foam can be used to quantify the effect of gum concentrations on the morphological features and physical properties of foams during freeze-drying.
由芦荟凝胶和瓜尔胶制备的冻干泡沫的物理特性
背景:泡沫是悬浮在由半冻干或粘性液相组成的分散相中的气体的胶体分散体。食品泡沫的物理性质是气泡特性及其空间排列的结果。目的:利用分形维数概念和图像分析技术,获得瓜尔胶和芦荟凝胶的泡沫,描述其在冷冻干燥过程中物理性质和微观结构的变化。方法:测定以蚕豆为原料制备的新鲜泡沫的孔隙率、密度和体积膨胀系数。对冻干泡沫的结构、颜色、孔隙率和微观结构进行了动力学研究。以泡沫的表面分形织构维数(FDSDBC)和微观结构(FDESEM)作为冻干后泡沫结构变化的指标。制备紫胶预泡用瓜尔胶浓度以w/w表示为F1(无胶对照)、F2(2%)、F3(4%)和F4(6%)。结果:获得了稳定的芦荟凝胶和瓜尔胶冻干泡沫。瓜尔胶的加入对新鲜泡沫和冻干泡沫的孔隙率、密度和体积膨胀系数有影响。在干燥过程中,冻干泡沫表面的拓扑结构发生了变化,导致与原始光滑表面相比具有较高的粗糙度。干燥泡沫样品的微观结构表明,预泡胶混合物的胶浓度与冷冻干燥前后的物理性质有关,如冷冻干燥过程中微观结构变化和表面粗糙度的增加。FDSDBC描述的泡沫表面粗糙度反映了样品的宏观物理变化,并与泡沫微观结构的变化相关,泡沫微观结构的变化由环境扫描电子显微镜ESEM显微照片(FDESEM)的分形维数描述。结论:通过对冻干泡沫的结构和孔隙率进行数字化分析,可以定量分析胶浓度对冻干过程中泡沫的形态特征和物理性质的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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