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用橙皮残渣稳定的双层乳液的喷雾干燥:工艺参数和收集位置的影响

Spray Drying of Double-Layer Emulsion Stabilised with an Orange Residue: Effect of Process Parameters and Collection Position.

作者信息

Umaña Mónica, Dalmau Esperanza, Rosselló Carmen, Eim Valeria, Simal Susana

机构信息

Department of Chemistry, University of the Balearic Islands, Ctra. Valldemossa km 7.5, 07122 Palma de Mallorca, Spain.

出版信息

Foods. 2025 Aug 21;14(16):2919. doi: 10.3390/foods14162919.

DOI:10.3390/foods14162919
PMID:40870830
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12385256/
Abstract

This study investigated the impact of spray-drying conditions, specifically inlet air temperature (Tin: 131-159 °C) and feed rate (FR: 4.9-8.4 g/min), on the microencapsulation of oil in a double-layer emulsion stabilised with orange residue flour (ORF) and soy protein. Powders were analysed separately from the drying chamber and the collector, focusing on yield, encapsulation efficiency, moisture, water activity (aw), oil oxidation, colour, and particle size. Chamber powders were more sensitive to Tin, where higher temperatures (155-159 °C) improved yield (up to 47% dry matter (dm)) but also increased oxidation (up to 134% above initial oil). Excessively high FR (8.4 g/min) reduced yield and raised aw (up to 0.39). Collector powders showed more stable yields (average 30 ± 2% dm) but lower encapsulation efficiency (80-86% for chamber vs. 70-77% for collector). Response surface methodology satisfactorily modelled key parameters (R up to 0.9). Optimisation showed that chamber performance was maximised at 146 °C and 4.9 g/min (predicted yield and aw of 41% and 0.25, respectively), while collector quality improved with slightly higher Tin (150 °C, predicted aw of 0.32). Separately analysing chamber and collector fractions provided novel insights into spray-drying dynamics. These findings highlight ORF as a promising wall material.

摘要

本研究调查了喷雾干燥条件,特别是进风温度(Tin:131 - 159°C)和进料速率(FR:4.9 - 8.4 g/min)对以橙渣粉(ORF)和大豆蛋白稳定的双层乳液中油微胶囊化的影响。分别对干燥室和收集器中的粉末进行分析,重点关注产率、包封效率、水分、水分活度(aw)、油氧化、颜色和粒径。干燥室中的粉末对进风温度更敏感,较高温度(155 - 159°C)提高了产率(干物质(dm)高达47%),但也增加了氧化(比初始油高134%)。过高的进料速率(8.4 g/min)降低了产率并提高了水分活度(高达0.39)。收集器中的粉末产率更稳定(平均30±2% dm),但包封效率较低(干燥室中为80 - 86%,收集器中为70 - 77%)。响应面法对关键参数进行了令人满意的建模(R高达0.9)。优化表明,干燥室性能在146°C和4.9 g/min时达到最大化(预测产率和水分活度分别为41%和0.25),而收集器质量在稍高的进风温度(150°C,预测水分活度为0.32)下有所改善。分别分析干燥室和收集器部分为喷雾干燥动力学提供了新的见解。这些发现突出了橙渣粉作为一种有前景的壁材。

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