An Overview of the Application of Blue Light-Emitting Diodes as a Non-Thermic Green Technology for Microbial Inactivation in the Food Sector

IF 5.3 2区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY Food Engineering Reviews Pub Date : 2023-08-19 DOI:10.1007/s12393-023-09355-1

Alessia Lena, Marilena Marino, Marisa Manzano, Clara Comuzzi, Michela Maifreni

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Abstract

Blue light is an emerging technology used for the decontamination of food contact surfaces and products. It is based on the activation of photosensitizers by light, determining the release of reactive oxygen species (ROS). ROS causes damage to bacterial cells leading to cell death. Several types of microbes may be treated, such as bacteria, yeasts, moulds and viruses, in planktonic or biofilm form. Blue light technology is affected by several factors: light parameters (i.e., irradiance, dose, wavelength), microbial parameters (i.e., pH, temperature, initial inoculum, grade of biofilm maturation) and surface parameters (i.e., material, roughness, and optical properties). In addition, it may be used alone or coupled with other technologies. The use of blue light shows several advantages, such as safety for food operators, and a lower release of chemicals in the environment. Moreover, it seems unlikely for bacteria to develop resistance to the blue light application.

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蓝光二极管作为一种非热绿色微生物灭活技术在食品行业的应用综述

蓝光是一种用于净化食品接触表面和产品的新兴技术。它的原理是通过光激活光敏剂，决定活性氧（ROS）的释放。ROS 会破坏细菌细胞，导致细胞死亡。可处理多种类型的微生物，如细菌、酵母菌、霉菌和病毒等浮游生物或生物膜形态的微生物。蓝光技术受多种因素影响：光参数（即辐照度、剂量、波长）、微生物参数（即 pH 值、温度、初始接种量、生物膜成熟度）和表面参数（即材料、粗糙度和光学特性）。此外，它还可单独使用或与其他技术结合使用。使用蓝光有几个优点，如对食品操作人员安全，在环境中释放的化学物质较少。此外，细菌似乎不太可能对蓝光产生抗药性。

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来源期刊

Food Engineering Reviews FOOD SCIENCE & TECHNOLOGY-

CiteScore

14.20

自引率

1.50%

发文量

审稿时长

>12 weeks

期刊介绍： Food Engineering Reviews publishes articles encompassing all engineering aspects of today’s scientific food research. The journal focuses on both classic and modern food engineering topics, exploring essential factors such as the health, nutritional, and environmental aspects of food processing. Trends that will drive the discipline over time, from the lab to industrial implementation, are identified and discussed. The scope of topics addressed is broad, including transport phenomena in food processing; food process engineering; physical properties of foods; food nano-science and nano-engineering; food equipment design; food plant design; modeling food processes; microbial inactivation kinetics; preservation technologies; engineering aspects of food packaging; shelf-life, storage and distribution of foods; instrumentation, control and automation in food processing; food engineering, health and nutrition; energy and economic considerations in food engineering; sustainability; and food engineering education.