Effect of the Spray Drying Process on the Quality of Coconut Powder Fortified with Calcium and Vitamins C, D3 and E

Advance Journal of Food Science and Technology Pub Date : 2018-11-10 DOI:10.19026/AJFST.16.5943

Lucas Aguirre Juan Carlos, Giraldo Giraldo German Antonio, C. Misael

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引用次数: 9

Abstract

The objective of this study was to optimize the process of Spray Drying (SD) for the obtaining of coconut powder fortified with Physiologically Active Compounds (PAC), according to the dryer's operating characteristics and the product, being (SD) is one of the most used technologies in the powder industry, guaranteeing good quality attributes for various applications in the food sector; it was used a response surface design based on five independent variables:: Maltodextrin (MD), Inlet Air Temperature (IAT), Outlet Air Temperature (OAT), Atomizing Disk Velocity (ADV) and drying Chamber Vacuum Pressure (VPC) and the dependent variables: yield (*R), Deposit Formation (DF) in the drying chamber, humidity (Xw), water activity (aw), Hygroscopicity (H), Solubility (S), wettability (Hu), color (L*, a* y b*), recovery of PAC (Ca, vitamins C, D3 and E), Peroxide Index (PI) and particle size (D10, D50 y D90). The results were analyzed statistically from the Statgraphics XVI.I software and through analysis of variance with 5% level of significance. In general, response variables were affected by all independent variables. The experimental optimization defined the CP+PAC process conditions as follows: IAT: 170°C; OAT: 85.8°C; ADV: 26676 rpm; VPC: 1.6” H2O; MD: 7.0%; and with quality attributes: Xw: 1.7±0.4%; aw: 0.171±0.018; H: 8.4±0.5%; S: 58.4±2.1%; Hu: 263.0±19.8s; L*: 79.5±0.9; a*: 1.5±0.1; b*: 9.5±0.4; PI: 2.4±1.3 meq H2O2/kg oil; DFC: 32.4±2.3%; *R: 44.0%; D10: 1.70±0.05 μm; D50: 8.46±2.09 μm; D90: 78.18±24.30 μm; Ca: 41.7±2.3%; Vit.C: 32.4±6.2%; Vit.D3: 7.8±1.8%; Vit.E: 6.1±1.9%; making it a hygroscopic product, potentially sensitive to oxidative processes, which can cause changes in color, strange flavors or odors.

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喷雾干燥工艺对加钙、维生素C、D3、E椰子粉品质的影响

本研究的目的是根据干燥机的工作特点和产品的特点，优化喷雾干燥(SD)工艺，以获得增强生理活性化合物(PAC)的椰子粉，喷雾干燥(SD)是粉末工业中使用最多的技术之一，保证了良好的品质属性，可用于食品行业的各种应用;采用基于麦芽糊精(MD)、进风口温度(IAT)、出风口温度(OAT)、雾化盘速度(ADV)和干燥室真空压力(VPC) 5个自变量和因变量的响应面设计:产率(*R)，干燥室内沉积形成(DF)，湿度(Xw)，水活度(aw)，吸湿性(H)，溶解度(S)，润湿性(Hu)，颜色(L*， a* y b*)， PAC (Ca，维生素C, D3和E)的回收率，过氧化物指数(PI)和粒度(D10, D50 y D90)。结果从Statgraphics XVI进行统计分析。I软件并通过5%显著水平的方差分析。总体而言，响应变量受所有自变量的影响。实验优化确定CP+PAC工艺条件为:IAT: 170℃;燕麦:85.8°C;ADV: 26676 rpm;Vpc: 1.6 " h2o;MD: 7.0%;质量属性:Xw: 1.7±0.4%;亚历山大-伍尔兹:0.171±0.018;H: 8.4±0.5%;S: 58.4±2.1%;胡:263.0±19.8年代;L *: 79.5±0.9;*: 1.5±0.1;b *: 9.5±0.4;PI: 2.4±1.3 meq H2O2/kg油;展开:32.4±2.3%;* R: 44.0%;D10: 1.70±0.05 μm;D50: 8.46±2.09 μm;D90: 78.18±24.30 μm;Ca: 41.7±2.3%;Vit.C: 32.4±6.2%;维特。D3: 7.8±1.8%;维特。艾凡:6.1±1.9%;使其成为吸湿性产品，对氧化过程可能敏感，这会导致颜色变化，奇怪的味道或气味。

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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Advance Journal of Food Science and Technology

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