商业噬菌体鸡尾酒治疗减少收获前农业用水中的婴儿沙门氏菌水平。

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

Journal of food protection Pub Date : 2025-08-26 DOI:10.1016/j.jfp.2025.100605

Alan Gutierrez , Zirui Ray Xiong , Shayla B. Johnson , Ajani A. Brooks , Ellen Gabriel , Adib Adnan , Amit Vikram , Mary Theresa Callahan , Manan Sharma

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引用次数: 0

摘要

收获前环境中受污染的灌溉水可导致与水果和蔬菜有关的疾病暴发。收获前的水可能受到细菌病原体的微生物污染，因此需要有效的水处理方法来减轻这种风险。本研究旨在评估商业噬菌体鸡尾酒对农业用水中婴儿沙门氏菌的功效。在不同pH值（6.5和8.4）和浊度水平（4、20、50和100 NTU）下制备的试验农业用水（TAW）培养基中接种抗萘啶酸的S.婴儿菌株（~ 6 log CFU/mL），进行三次试验，并用噬菌体滴度为8 log PFU/mL的噬菌体鸡尾酒（SalmoFresh™）处理。在25°C下，摇晃（250 rpm） 5分钟接触时间后采集水样。此外，收集的池塘水，自然（非无菌）和高压灭菌，接种婴儿链球菌（~ 4 log PFU/mL），并用噬菌体混合物（7 log PFU/mL或8 log PFU/mL）在12°C或32°C下处理5、10或30分钟，进行三次试验。样品经添加50 μg/mL钠啶酸的XLD或TSA上涂片计数。在TAW中，经过5分钟噬菌体处理后，S. Infantis水平平均降低了1.0 log CFU/mL，在所有pH和浊度水平的测试中，降低没有显著差异（p > 0.05）。在池塘水（天然和蒸压）中，只有当噬菌体滴度为8 log CFU/mL时，婴儿链球菌才会减少，在32°C下，5、10和30分钟后，平均减少1.04、1.50和1.67 log CFU/mL。在12°C下，5分钟、10分钟和30分钟后，平均减量分别为0.90、1.15和1.36 log CFU/mL。这些结果表明，针对沙门氏菌的商业裂解噬菌体鸡尾酒在各种条件下（pH、浊度、温度）都是有效的，可以考虑与其他技术一起降低农业用水中的沙门氏菌水平。

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Commercial Bacteriophage Cocktail Treatment Reduces Salmonella Infantis Levels in Pre-harvest Agricultural Water

Contaminated irrigation water in the preharvest environment can lead to outbreaks associated with fruits and vegetables. The potential of microbial contamination in preharvest waters by bacterial pathogens has created an ongoing demand for effective water treatment methods to mitigate this risk. This study sought to evaluate the efficacy of a commercial bacteriophage cocktail against Salmonella Infantis in agricultural water. A test agricultural water (TAW) medium prepared at different pH (6.5 and 8.4) and turbidity levels (4, 20, 50, and 100 NTU) was inoculated with a nalidixic acid resistant strain of S. Infantis (∼6 log CFU/mL), in triplicate trials, and treated with a bacteriophage cocktail (SalmoFresh™) at a phage titer of 8 log PFU/mL. Water samples were taken after a 5-minute contact time, with shaking (250 rpm), at 25 °C. Additionally, collected pond water, natural (nonsterile) and autoclaved, was inoculated with S. Infantis (∼4 log CFU/mL) and treated with bacteriophage cocktail (7 log PFU/mL or 8 log PFU/mL) at either 12 °C or 32 °C for 5, 10, or 30 min in triplicate trials. Samples were enumerated by plating onto XLD or TSA supplemented with 50 μg/mL Nalidixic acid. In TAW, S. Infantis levels were reduced by an average of 1.0 log CFU/mL after the 5-minute phage treatment, with no significant differences in reductions across all pH and turbidity levels tested (p > 0.05). In pond water (natural and autoclaved), S. Infantis reductions only occurred when the phage titer was 8 log PFU/mL, with average reductions of 1.04, 1.50, and 1.67 log CFU/mL after 5, 10, and 30 min, respectively, at 32 °C. At 12 °C, average reductions were 0.90, 1.15, and 1.36 log CFU/mL after 5, 10, and 30 min, respectively. These results demonstrate that commercial lytic phage cocktail specific for Salmonella are effective in water across various conditions (pH, turbidity, temperature) and may be considered with other technologies to reduce Salmonella levels in agricultural water.

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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.