Microbial food spoilage: impact, causative agents and control strategies

Microbial food spoilage is a major contributor to food waste and, hence, to the negative environmental sustainability impacts of food production and processing. Globally, it is estimated that 15–20% of food is wasted, with waste, by definition, occurring after primary production and harvesting (for...

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Bibliographic Details
Published in:Nature reviews. Microbiology 2024-09, Vol.22 (9), p.528-542
Main Authors: Snyder, Abigail B., Martin, Nicole, Wiedmann, Martin
Format: Article
Language:English
Subjects:
631/326/193/2096
631/326/2522
631/326/41/2095
Aerobic microorganisms
Anaerobic microorganisms
Beverages
Biomedical and Life Sciences
Environmental impact
Food
Food processing
Food processing industry wastes
Food production
Food spoilage
Food waste
Households
Infectious Diseases
Life Sciences
Medical Microbiology
Microbicides
Microbiology
Microorganisms
Parasitology
Primary production
Raw materials
Review Article
Spoilage
Virology
Water activity
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Summary:Microbial food spoilage is a major contributor to food waste and, hence, to the negative environmental sustainability impacts of food production and processing. Globally, it is estimated that 15–20% of food is wasted, with waste, by definition, occurring after primary production and harvesting (for example, in households and food service establishments). Although the causative agents of food spoilage are diverse, many microorganisms are major contributors across different types of foods. For example, the genus Pseudomonas causes spoilage in various raw and ready-to-eat foods. Aerobic sporeformers (for example, members of the genera Bacillus , Paenibacillus and Alicyclobacillus ) cause spoilage across various foods and beverages, whereas anaerobic sporeformers (for example, Clostridiales) cause spoilage in a range of products that present low-oxygen environments. Fungi are also important spoilage microorganisms, including in products that are not susceptible to bacterial spoilage due to their low water activity or low pH. Strategies that can reduce spoilage include improved control of spoilage microorganisms in raw material and environmental sources as well as application of microbicidal or microbiostatic strategies (for example, to products and packaging). Emerging tools (for example, systems models and improved genomic tools) represent an opportunity for rational design of systems, processes and products that minimize microbial food spoilage. In this Review, Snyder et al. discuss the global impacts of food spoilage, mechanisms and causative agents, and strategies and emerging tools to control microbial food spoilage.
ISSN:1740-1526
1740-1534
1740-1534
DOI:10.1038/s41579-024-01037-x