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- ItemImpact of cold atmospheric pressure plasma processing on storage of blueberries(Oxford [u.a.] : Wiley-Blackwell, 2020) Pathak, Namrata; Grossi Bovi, Graziele; Limnaios, Athanasios; Fröhling, Antje; Brincat, Jean-Pierre; Taoukis, Petros; Valdramidis, Vasilis P.; Schlüter, OliverThe current study aimed at investigating the impact of nitrogen (N)-generated cold atmospheric pressure plasma (CAPP) treatment on blueberries focusing on the overall impact on berry quality and microbial load along a storage period of 10 days. Blueberries were treated for 0 (control), 5, and 10 min. Assessment of fruit quality (°Bx, ascorbic acid, anthocyanins, titratable acidity, elasticity, and color parameters) and microbial analysis was performed. Results showed that CAPP treatment was more effective in inhibiting bacterial growth than fungal growth and during the subsequent storage, the quality parameters did not differ significantly from the control, under the same conditions. The study supports N-generated CAPP as a disinfection technique to reduce microbial load in blueberries without significantly impacting most quality parameters. Practical applications: Over the last decades, foodborne illness outbreaks around the world have been associated with berries. For that reason, due to the increasing consumption of berries it is paramount to study technologies that can eliminate pathogens responsible for such outbreaks. Cold atmospheric pressure plasma (CAPP) can be a promising technology to be used as an alternative to traditional decontamination methods of food. In this context, this study explored the effect and efficiency of this novel technology on reduction of native microflora and its impact on the physical and chemical properties of blueberries treated by nitrogen (N)-generated CAPP with subsequent storage of 10 days. Results of this work confirmed that such technology has high potential application for decontamination of berries without significantly impacting most quality parameters and thereby can be a potential technology for industrial applications. © 2020 The Authors. Journal of Food Processing and Preservation published by Wiley Periodicals LLC.
- ItemCold atmospheric pressure plasma and low energy electron beam as alternative nonthermal decontamination technologies for dry food surfaces: A review(Amsterdam [u.a.] : Elsevier Science, 2018) Hertwig, Christian; Meneses, Nicolas; Mathys, AlexanderBackground: Dry food products are often highly contaminated, and dry stress-resistant microorganisms, such as certain types of Salmonella and bacterial spores, can be still viable and multiply if the product is incorporated into high moisture food products or rehydrated. Traditional technologies for the decontamination of these products have certain limitations and drawbacks, such as alterations of product quality, environmental impacts, carcinogenic potential and/or lower consumer acceptance. Cold atmospheric pressure plasma (CAPP) and low energy electron beam (LEEB) are two promising innovative technologies for microbial inactivation on dry food surfaces, which have shown potential to solve these certain limitations. Scope and approach: This review critically summarizes recent studies on the decontamination of dry food surfaces by CAPP and LEEB. Furthermore, proposed inactivation mechanisms, product-process interactions, current limitations and upscaling potential, as well as future trends and research needs for both emerging technologies, are discussed. Key findings and conclusions: CAPP and LEEB are nonthermal technologies with a high potential for the gentle decontamination of dry food surfaces. Both technologies have similarities in their inactivation mechanisms. Due to the limited penetration depth of both technologies, product-process interactions can be minimized by maintaining product quality. A first demonstrator with Technology Readiness Level (TRL) 7 for LEEB has already been introduced into the food industry for the decontamination of herbs and spices. Compared with LEEB, CAPP is at the advanced development stage with TRL 5, for which further work is essential to design systems that are scalable to industrial requirements. © 2018 The Authors