Optimizing crispness and nutrient retention in carrot snacks: Multi-stage drying via microwave-infrared and negative pressure puffing with moisture-dependent transition

IF 6.8 1区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY

Innovative Food Science & Emerging Technologies Pub Date : 2025-08-15 DOI:10.1016/j.ifset.2025.104171

Hao Zhang , Bo Wang , Weiqiao Lv , Hongwei Xiao

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引用次数: 0

Abstract

This study aims to optimize the crispness and nutrient retention of ready-to-eat carrot snacks by investigating a multi-stage combined drying process of microwave-infrared vibrating bed drying (MIVBD) and pulse-spouted microwave vacuum drying (PSMVD). Four groups of combined drying experiments were designed with moisture content as the process transition point (30 %, 40 %, 50 %, and 60 % w.b.)—denoted as MI → PS-X, where MI refers to MIVBD, PS refers to PSMVD, and X represents the threshold (e.g., 0.5 for 50 % w.b.)—and compared with single drying processes to systematically analyze drying characteristics, physical properties (hardness, brittleness, color, microstructure, rehydration rate), nutritional components (total phenolics, carotenoids), and antioxidant activity. The results showed that MIVBD had the highest drying efficiency (80 ± 2.13 min), while PSMVD formed a porous structure through negative pressure puffing, resulting in the best brittleness (31.18 ± 1.11 peak numbers). When the critical moisture content was 50–60 %, the drying time of combined drying was 21.5–25.4 % shorter than that of PSMVD, and the brittleness (24.98–27.73 peaks) was close to that of single PSMVD. The MI → PS-0.5 group had the highest rehydration rate and moderate hardness (1602.52 g) due to its honeycomb-like porous structure with moderate wall thickness. PSMVD retained carotenoids best (26 % loss), while the MI → PS-0.6 group exhibited the highest antioxidant activity (DPPH scavenging rate 0.53 mg TE/g) due to the controlled balance between phenolic retention and Maillard reaction product. Scanning electron microscopy and low-field nuclear magnetic resonance analysis showed that combined drying at higher critical moisture content (≥50 %) could form well-connected “sponge-like” pore structures, improving crispness and rehydration speed, but moisture-proof packaging was required. Considering drying efficiency, quality, and nutrient retention, the MI → PS-0.5 process provides a new path for the industrial production of ready-to-eat vegetable snacks through a segmented mechanism of “rapid dehydration-structural expansion”.

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优化胡萝卜零食的脆度和营养保留：微波红外和负压膨化多阶段干燥与水分依赖过渡

本研究通过微波-红外振动床干燥（MIVBD）和脉冲喷射微波真空干燥（PSMVD）多阶段联合干燥工艺，优化即食胡萝卜零食的脆度和营养保留。以水分含量为工艺过渡点（30%、40%、50%和60% w.b）设计四组组合干燥实验，用MI→PS-X表示，其中MI为MIVBD， PS为PSMVD， X为阈值（如0.5为50% w.b），与单一干燥工艺进行比较，系统分析干燥特性、物理性质（硬度、脆性、颜色、微观结构、复水化率）、营养成分(总酚类物质、类胡萝卜素)和抗氧化活性。结果表明，MIVBD的干燥效率最高（80±2.13 min），而PSMVD通过负压膨化形成多孔结构，脆性最佳（31.18±1.11个峰数）。临界含水率为50 ~ 60%时，复合干燥的干燥时间比PSMVD短21.5 ~ 25.4%，脆性（24.98 ~ 27.73峰）与单一PSMVD接近。MI→PS-0.5组由于具有蜂窝状多孔结构，壁厚适中，复水率最高，硬度适中（1602.52 g）。PSMVD对类胡萝卜素的保留效果最好（损失26%），而MI→PS-0.6组由于酚类保留和美拉德反应产物之间的平衡得到控制，具有最高的抗氧化活性（DPPH清除率0.53 mg TE/g）。扫描电镜和低场核磁共振分析表明，在较高的临界含水率（≥50%）下联合干燥可以形成连接良好的“海绵状”孔隙结构，提高了松脆度和复水速度，但需要防潮包装。MI→PS-0.5工艺综合考虑干燥效率、质量和营养保留，通过“快速脱水-结构膨胀”的分段机制，为即食蔬菜小吃的工业化生产提供了一条新途径。

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来源期刊

Innovative Food Science & Emerging Technologies 工程技术-食品科技

CiteScore

12.00

自引率

6.10%

发文量

259

审稿时长

25 days

期刊介绍： Innovative Food Science and Emerging Technologies (IFSET) aims to provide the highest quality original contributions and few, mainly upon invitation, reviews on and highly innovative developments in food science and emerging food process technologies. The significance of the results either for the science community or for industrial R&D groups must be specified. Papers submitted must be of highest scientific quality and only those advancing current scientific knowledge and understanding or with technical relevance will be considered.