Synergistic Drying Solutions: Combining Vacuum and Infrared Techniques for Optimal Persimmon Preservation

IF 3.2 2区农林科学 Q2 FOOD SCIENCE & TECHNOLOGY

Journal of Food Science Pub Date : 2025-07-05 DOI:10.1111/1750-3841.70347

Alfadhl Yahya Alkhaled, Kemal Çağatay Selvi, Abraham Kabutey, Cestmir Mizera, Petr Hrabe, Jaroslava Svobodová, Esra Koçak, David Herák

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Abstract

This study evaluated vacuum drying (VD) and infrared drying (IRD) methods for persimmon, including individual and two-step sequential processes (VD followed by IRD and vice versa). The combined drying strategies were selected to harness the rapid surface heating of IRD and the low-temperature, low-oxygen benefits of VD, aiming to overcome limitations of single drying methods such as extended drying times and nutrient degradation. Drying experiments were conducted using laboratory-scale equipment at 50–70°C, for VD, with a vacuum pressure of 50 mbar (absolute pressure) and a pump speed of 2 L/s. Results showed a significant effect of drying combination strategies on drying rate, duration, effective moisture diffusivity, shrinkage, activation energy, color characteristics, microstructure, and phytochemical constituents of persimmon. The shortest drying times were recorded for IRD (240 min), followed by VD + IRD (343 min) and IRD + VD (376 min), whereas VD required the longest (520 min). Effective moisture diffusivity ranged from 1.42 × 10⁻⁹ m²/s for VD at 50°C (VD-50) to 7.83 × 10⁻⁹ m²/s for IRD at 70°C (IRD-70), with both individual IRD-70 and a combination of IRD + VD demonstrating improved moisture transfer performance. The IRD + VD combination resulted in the best microstructure preservation and showed lower shrinkage compared to other drying strategies. Moreover, this combination best preserved the persimmon color with the lowest total color change (ΔE = 5.591), whereas VD showed the highest (ΔE = 35.875). Activation energy was lowest in IRD + VD (13.98 kJ/mol), followed by VD + IRD (18.61 kJ/mol), with higher values in VD (34.08 kJ/mol) and IRD (22.75 kJ/mol). Phytochemical analysis showed IRD (total phenolic content [TPC] = 35.79 mgGAE/g, total flavonoid content [TFC] = 54.83 mgQE/g) and IRD + VD (TPC = 17.02 mgGAE/g, TFC = 58.52 mgQE/g) retaining the highest bioactive compounds. This study contributes to optimizing drying techniques for persimmon, enhancing energy efficiency, preserving nutritional quality, and supporting sustainable food processing, making it relevant for the food industry, food engineering, and food science fields.

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协同干燥解决方案：真空和红外技术相结合的最佳柿子保存

本研究评估了柿子的真空干燥（VD）和红外干燥（IRD）方法，包括单独和两步顺序干燥（VD后IRD，反之亦然）。为了克服单一干燥方法存在的干燥时间长、养分降解等缺点，选择了复合干燥策略，以利用IRD的快速表面加热和VD的低温、低氧优势。干燥实验在实验室规模的设备上进行，温度为50 - 70°C，真空压力为50 mbar（绝对压力），泵速为2 L/s。结果表明，不同干燥组合策略对柿子的干燥速率、干燥持续时间、有效水分扩散率、收缩率、活化能、颜色特征、微观结构和植物化学成分均有显著影响。干燥时间最短的是IRD (240 min)，其次是VD + IRD （343 min）和IRD + VD (376 min)，而VD所需的干燥时间最长（520 min）。50°C时VD的有效水分扩散系数为1.42 × 10−9 m2/s (VD-50)， 70°C时IRD的有效水分扩散系数为7.83 × 10−9 m2/s (IRD-70)，单独的IRD-70和IRD + VD的组合都显示出改善的水分传递性能。与其他干燥策略相比，IRD + VD组合的显微结构保存效果最好，收缩率也较低。该组合对柿子颜色的保存效果最好，总颜色变化最小（ΔE = 5.591）， VD最大（ΔE = 35.875）。IRD + VD的活化能最低（13.98 kJ/mol），其次是VD + IRD (18.61 kJ/mol)， VD和IRD的活化能最高（34.08 kJ/mol）和22.75 kJ/mol。植物化学分析表明，IRD（总酚含量[TPC] = 35.79 mgGAE/g，总黄酮含量[TFC] = 54.83 mgQE/g）和IRD + VD （TPC = 17.02 mgGAE/g, TFC = 58.52 mgQE/g）保留了最高的生物活性化合物。该研究有助于优化柿子干燥工艺，提高能源效率，保持营养品质，支持可持续食品加工，在食品工业、食品工程和食品科学领域具有重要意义。

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来源期刊

Journal of Food Science 工程技术-食品科技

CiteScore

7.10

自引率

2.60%

发文量

412

审稿时长

3.1 months

期刊介绍： The goal of the Journal of Food Science is to offer scientists, researchers, and other food professionals the opportunity to share knowledge of scientific advancements in the myriad disciplines affecting their work, through a respected peer-reviewed publication. The Journal of Food Science serves as an international forum for vital research and developments in food science. The range of topics covered in the journal include: -Concise Reviews and Hypotheses in Food Science -New Horizons in Food Research -Integrated Food Science -Food Chemistry -Food Engineering, Materials Science, and Nanotechnology -Food Microbiology and Safety -Sensory and Consumer Sciences -Health, Nutrition, and Food -Toxicology and Chemical Food Safety The Journal of Food Science publishes peer-reviewed articles that cover all aspects of food science, including safety and nutrition. Reviews should be 15 to 50 typewritten pages (including tables, figures, and references), should provide in-depth coverage of a narrowly defined topic, and should embody careful evaluation (weaknesses, strengths, explanation of discrepancies in results among similar studies) of all pertinent studies, so that insightful interpretations and conclusions can be presented. Hypothesis papers are especially appropriate in pioneering areas of research or important areas that are afflicted by scientific controversy.