Application of atmospheric cold plasma (ACP) for processing of raw bovine colostrum: Investigation of antimicrobial efficacy of different ACP treatments

IF 3.1 3区农林科学 Q2 FOOD SCIENCE & TECHNOLOGY

International Dairy Journal Pub Date : 2024-11-12 DOI:10.1016/j.idairyj.2024.106140

Negar Ravash , Javad Hesari , Sirous Khorram , M.S. Roopesh

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Abstract

As a rich source of bioactive components, bovine colostrum (BC)¹ can be used to produce valuable nutraceuticals. Achieving this goal with common thermal pasteurization processes is challenging due to the heat-sensitive nature of raw BC. This research aimed to investigate the potential of atmospheric cold plasma (ACP) as a novel non-thermal process in inactivating the microbial population in BC. Raw BC was treated with different ACP treatments, including direct dielectric barrier discharge (DBD) in both static and continuous modes, indirect DBD, corona discharge, and gliding arc discharge. The occurrence of creaming and curdling of BC during the treatments was one of the challenges of this research, which was the most and least severe during static and continuous treatments, respectively. The continuous and the indirect DBD treatments were the most and least effective in terms of microbial inactivation. The inactivation of natural microflora with the continuous ACP at the voltage of 15 kV for 20 min was approximately 98%. The indirect DBD treatment led to an increase in the microbial population of BC. In addition, the initial microbial population significantly affected the antimicrobial efficacy of ACP. Treatment voltage and time had a significant effect on the creaming and curdling, natural microflora population, and the total coliform population of the treated samples. The voltage of 14.5 kV and the exposure time of 14.2 min were determined as optimal treatment conditions by response surface methodology (RSM) to achieve the maximum reduction of microbial population, without pH changing of ACP-treated BC. The optimal treatment conditions of ACP reduced the total plate count and total coliform count of raw BC by 1.41 and 3.55 log CFU/ml, respectively, with a minor change in pH. These results promise the potential of ACP technology for BC processing.

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应用常压冷等离子体（ACP）处理生牛初乳：不同 ACP 处理的抗菌效果研究

作为生物活性成分的丰富来源，牛初乳（BC）1 可用于生产有价值的营养保健品。由于牛初乳原料对热敏感，使用普通热巴氏杀菌工艺实现这一目标具有挑战性。本研究旨在调查大气冷等离子体（ACP）作为一种新型非热工艺在灭活 BC 微生物群方面的潜力。对未加工的 BC 采用了不同的 ACP 处理方法，包括静态和连续模式的直接介质阻挡放电（DBD）、间接 DBD、电晕放电和滑弧放电。处理过程中 BC 起泡和凝结是本研究的挑战之一，在静态和连续处理过程中，起泡和凝结的严重程度分别最大和最小。就微生物灭活而言，连续和间接 DBD 处理的效果最好，效果最差。在 15 kV 的电压下连续使用 ACP 20 分钟，天然微生物菌群的灭活率约为 98%。间接 DBD 处理导致 BC 微生物数量增加。此外，初始微生物数量对 ACP 的抗菌效果也有显著影响。处理电压和时间对处理样品的起皱和凝结、天然微生物菌群和总大肠菌群有显著影响。通过响应面法（RSM）确定了 14.5 千伏的电压和 14.2 分钟的暴露时间为最佳处理条件，从而在不改变 ACP 处理 BC 的 pH 值的情况下最大程度地减少了微生物数量。在 ACP 的最佳处理条件下，生 BC 的总菌落总数和总大肠菌群数分别减少了 1.41 和 3.55 log CFU/ml，pH 值变化不大。这些结果证明了 ACP 技术在加工 BC 方面的潜力。

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来源期刊

International Dairy Journal 工程技术-食品科技

CiteScore

6.50

自引率

9.70%

发文量

200

审稿时长

49 days

期刊介绍： The International Dairy Journal publishes significant advancements in dairy science and technology in the form of research articles and critical reviews that are of relevance to the broader international dairy community. Within this scope, research on the science and technology of milk and dairy products and the nutritional and health aspects of dairy foods are included; the journal pays particular attention to applied research and its interface with the dairy industry. The journal''s coverage includes the following, where directly applicable to dairy science and technology: • Chemistry and physico-chemical properties of milk constituents • Microbiology, food safety, enzymology, biotechnology • Processing and engineering • Emulsion science, food structure, and texture • Raw material quality and effect on relevant products • Flavour and off-flavour development • Technological functionality and applications of dairy ingredients • Sensory and consumer sciences • Nutrition and substantiation of human health implications of milk components or dairy products International Dairy Journal does not publish papers related to milk production, animal health and other aspects of on-farm milk production unless there is a clear relationship to dairy technology, human health or final product quality.