Salmonella spp. Inactivation During Hot Air Drying of Apples: Influence of Temperature, Bed Depth, and Air Velocity

IF 2.8 4区农林科学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Journal of food protection Pub Date : 2025-08-11 DOI:10.1016/j.jfp.2025.100597

Xiyang Liu , Elizabeth M. Grasso-Kelley , Alvin Lee , Lilybell Warda , Nathan M. Anderson

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引用次数: 0

Abstract

Dried fruit has been linked to recalls and outbreaks due to microbiological hazards. While most drying processes are optimized for product quality, microbiological safety may not always be prioritized. The food industry is required to validate process preventive controls to ensure they significantly minimize or prevent microbial hazards. This study aimed to evaluate the combined effects of temperature, drying bed depth, and air velocity on the inactivation of Salmonella on apple cubes. A cocktail of six Salmonella serovars was inoculated onto fresh Gala apple cubes (∼0.256 cm³). A single layer of Salmonella-inoculated apple cubes was dyed red and placed atop un-inoculated cubes in a drying chamber to achieve final bed depths of 5.1, 8.9, or 12.7 cm. Apple cubes were dried at 88, 104, or 120 °C with air velocities of 2.10, 2.95, or 3.82 m/s. At multiple time points (n ≥ 5), samples were collected from the inoculated, dyed apple cubes on the top layer for water activity measurement and Salmonella enumeration. Across all drying conditions, an initial stable stage of apple a_w and Salmonella populations was observed with varying durations followed by a rapid decrease in both. The overall effect of drying temperature, bed depth, and air velocity on microbial inactivation followed a consistent pattern: Higher temperature reduced the drying time required to achieve comparable Salmonella reductions as elevated product temperature enhanced microbial inactivation. Similarly, lower bed depth allowed the thinner apple layers to reach higher temperatures more rapidly, accelerating microbial reduction. Increased air velocity shortened the constant-rate drying period, promoted a faster temperature increase in the apple cubes, and resulted in higher lethality within a shorter drying period. Although a 5-log reduction of Salmonella was achieved at the end of drying under all but one condition, the reductions were reached at varying endpoint water activity levels.

查看原文本刊更多论文

苹果热风干燥过程中沙门氏菌的失活：温度、床深和风速的影响。

由于微生物危害，干果与召回和疫情有关。虽然大多数干燥过程都针对产品质量进行了优化，但微生物安全可能并不总是优先考虑的。食品工业需要验证过程预防控制，以确保它们显著地减少或防止微生物危害。本研究旨在评价温度、干燥床深度和空气流速对苹果块沙门氏菌灭活的综合影响。将六种沙门氏菌血清型的混合物接种到新鲜的Gala苹果块（~ 0.256 cm3）上。将单层接种过沙门氏菌的苹果块染成红色，放在干燥室中未接种过的苹果块上，最终达到5.1、8.9或12.7厘米的深度。苹果块在88、104或120°C下干燥，风速为2.10、2.95或3.82 m/s。在多个时间点（n≥5），从接种后染色的苹果立方体的最上层采集样品，进行水活度测定和沙门氏菌计数。在所有干燥条件下，观察到苹果aw和沙门氏菌种群的初始稳定阶段，持续时间不同，随后两者迅速下降。干燥温度、床层深度和风速对微生物灭活的总体影响遵循一致的模式：较高的温度减少了减少沙门氏菌所需的干燥时间，而升高的产品温度增强了微生物灭活。同样，较低的床层深度可以使较薄的苹果层更快地达到较高的温度，从而加速微生物的减少。风速的增大缩短了等速干燥时间，促进了苹果块的升温速度加快，在更短的干燥时间内导致了更高的致死率。尽管在除一种条件外的所有条件下，在干燥结束时都实现了沙门氏菌的5对数减少，但在不同的终点水活度水平下达到了减少。

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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来源期刊

Journal of food protection 工程技术-生物工程与应用微生物

CiteScore

4.20

自引率

5.00%

发文量

296

审稿时长

2.5 months

期刊介绍： The Journal of Food Protection® (JFP) is an international, monthly scientific journal in the English language published by the International Association for Food Protection (IAFP). JFP publishes research and review articles on all aspects of food protection and safety. Major emphases of JFP are placed on studies dealing with: Tracking, detecting (including traditional, molecular, and real-time), inactivating, and controlling food-related hazards, including microorganisms (including antibiotic resistance), microbial (mycotoxins, seafood toxins) and non-microbial toxins (heavy metals, pesticides, veterinary drug residues, migrants from food packaging, and processing contaminants), allergens and pests (insects, rodents) in human food, pet food and animal feed throughout the food chain; Microbiological food quality and traditional/novel methods to assay microbiological food quality; Prevention of food-related hazards and food spoilage through food preservatives and thermal/non-thermal processes, including process validation; Food fermentations and food-related probiotics; Safe food handling practices during pre-harvest, harvest, post-harvest, distribution and consumption, including food safety education for retailers, foodservice, and consumers; Risk assessments for food-related hazards; Economic impact of food-related hazards, foodborne illness, food loss, food spoilage, and adulterated foods; Food fraud, food authentication, food defense, and foodborne disease outbreak investigations.