Mechanistic modeling of the dynamics of phage attack during milk acidification in the cheese-making process

IF 5.3 2区农林科学 Q1 ENGINEERING, CHEMICAL

Journal of Food Engineering Pub Date : 2024-10-10 DOI:10.1016/j.jfoodeng.2024.112329

Michèle Bou Habib , Emmanuel Bernuau , Benjamín José Sánchez , Dominique Swennen , Ahmad A. Zeidan , Ioan-Cristian Trelea , Jannik Vindeloev

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引用次数: 0

Abstract

Bacteriophage attacks represent a major threat in the dairy industry. Here, an unstructured mechanistic model predicting the dynamics of milk acidification in case of phage attack was developed and experimentally validated. Multiple acidification experiments were run with different combinations of initial phage titers and bacterial concentrations and the resulting pH dynamics were recorded. The model could successfully predict the success or failure of milk acidification. Using the model, important biological parameters were deduced from simple, low-cost acidification measurements. These parameters included bacteria’s maximum growth and lysis rates, phages’ burst size, etc. Sensitivity analysis helped identify biologically relevant aspects of phage-host interactions. Growth and lysis kinetics were shown to have the most important impacts. This knowledge can be used to develop easy routine strategies to fight phage attack in the dairy industry. The model can be used to raise awareness amongst cheese makers on the importance of cleaning to avoid food and material waste.

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奶酪制作过程中牛奶酸化过程中噬菌体攻击动态的机理建模

噬菌体攻击是乳制品行业的一大威胁。在此，我们建立了一个非结构化机理模型，预测噬菌体侵袭情况下牛奶酸化的动态，并进行了实验验证。使用不同的初始噬菌体滴度和细菌浓度组合进行了多次酸化实验，并记录了由此产生的 pH 动态变化。该模型可成功预测牛奶酸化的成败。利用该模型，可以从简单、低成本的酸化测量中推断出重要的生物参数。这些参数包括细菌的最大生长率和溶解率、噬菌体的爆发大小等。敏感性分析有助于确定噬菌体-宿主相互作用的生物学相关方面。结果表明，生长和裂解动力学具有最重要的影响。这些知识可用于制定简便的常规策略，以对抗噬菌体对乳制品行业的侵袭。该模型可用于提高奶酪制造商对清洁重要性的认识，以避免食物和材料浪费。

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来源期刊

Journal of Food Engineering 工程技术-工程：化工

CiteScore

11.80

自引率

5.50%

发文量

275

审稿时长

24 days

期刊介绍： The journal publishes original research and review papers on any subject at the interface between food and engineering, particularly those of relevance to industry, including: Engineering properties of foods, food physics and physical chemistry; processing, measurement, control, packaging, storage and distribution; engineering aspects of the design and production of novel foods and of food service and catering; design and operation of food processes, plant and equipment; economics of food engineering, including the economics of alternative processes. Accounts of food engineering achievements are of particular value.