Effect of a non-thermal atmospheric pressure plasma jet on four different yeasts

Siadati, Seyedehneda; Petkova, Maria; Kenari, Ali Jamaati; Kyzek, Stanislav; Gálová, Eliška; Zahoranová, Anna

doi:10.1088/1361-6463/abb624

Cited by 7 publications

(3 citation statements)

References 40 publications

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“…Exploratory research has showcased the efficacy of plasma in combating the causative agents of nail fungal infections across pathogen models, detached nail models, and clinical trials [1,84,85]. White Candida albicans and Trichophyton mentagrophytes treated with atmospheric pressure plasma jet (APPJ) displayed inhibited growth, reduced adhesion, and decreased infectivity in a nail model [86,87]. Furthermore, findings for other dermatophytes, such as Epidermophyton floccosum and verrucous Trichophyton, affirmed that CAP can impede the growth and infection of skin fungi [88,89].…”

Section: Effects Of Cap On Fungimentioning

confidence: 99%

Advancements in Cold Atmospheric Plasma for Skin Disease Treatment and Skincare: A Brief Update

Khalaf,

Oglah,

Liu

2023

Preprint

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Cold atmospheric plasma (CAP) has emerged as a promising therapeutic technology, distinguished by its safety, efficiency, and minimal side effects. With increasing applications in dermatology, CAP demonstrates antimicrobial efficacy against bacteria, viruses, and fungi, supports tissue proliferation and wound healing, and hinders the growth and migration of tumor cells. This review encompasses the concept, physical characteristics, and current research applications of CAP in dermatology. CAP, a gas cloud produced by ionizing gases, operates at room temperature, ensuring safety and efficacy in dermatological use. Its effects are mediated through active components like reactive oxygen and nitrogen species (RONS) and ultraviolet radiation. The extensive research covered in this paper explores CAP's applications in skin infections, immune-related diseases, and tumor diseases. As a biologically suitable technology, cold atmospheric pressure plasma finds widespread use in medicine, including medical device sterilization, dentistry, oncology, and dermatology. The direct and indirect forms of CAP applications, including plasma-activated liquids, complement each other. CAP holds promise as a dermatological treatment technique, but further exploration and research are needed. This article briefly explores CAP's diverse applications and potential utility within dermatology. The objective is to enhance the progress of plasma medicine by furnishing a concise overview of the applications of this groundbreaking technology in dermatological contexts.

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Section: Effects Of Cap On Fungimentioning

confidence: 99%

Advancements in Cold Atmospheric Plasma for Skin Disease Treatment and Skincare: A Brief Update

Khalaf,

Oglah,

Liu

2023

Preprint

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“…Plasma treatment can efficiently inactivate many microorganisms (prokaryotes: bacteria and eukaryotes: fungus & yeast), including spores and viruses (Nishime et al, 2017; Phan et al, 2017; Siadati et al, 2020). Research on the application of plasma technology usually focused on the sterility of fruits & vegetables, seafood, meat & meat products, milk‐based products, cereal grains, etc.…”

Section: Introductionmentioning

confidence: 99%

Cold plasma for microbial safety: Principle, mechanism, and factors responsible

Punia

Suri

Nayi

et al. 2022

Food Processing Preservation

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Elimination of microbiological contamination of food products is predominant for consumer food safety. Cold plasma (CP) technology has evolved as a unique, cost‐effective, and environmentally friendly solution to microbial decontamination that is gaining popularity due to its great efficacy in ensuring food safety. As increasing the demand of food industries to produce and supply the safe food with minimal processing. Cold plasma application is being used to sanitize the food surface to be used for different food industry sectors for microbial inactivation. The rapid microbial inactivation obtained by cold plasma has sparked a surge in interest in the field. The current review will give a critical snapshot of the potential application of cold plasma in microbial safety, including food safety, quality, and enzyme inactivation. The rapid microbiological inactivation achieved with cold plasma has led to an interest in this subject. Further, factors affecting, that is, food composition, PH, water activity, and microorganism type for microbial inactivation by cold plasma, are summarized and discussed. There is an increasing demand for food industries to produce and supply safe food with minimal processing. Cold plasma has the potential to sanitize the food surface to be used in different food industry sectors for microbial inactivation. Novelty impact statement This review discussed the principle, equipment, and process mechanism of cold plasma. The mechanism of microbial inactivation by cold plasma was summarized. Also, the effect of cold plasma on factors including food composition, pH, water activity, microorganism type, and enzyme inactivation was explored.

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“…Due to the characteristics of high chemical activity and low temperature, there is an increasing interest in the application of atmospheric-pressure nonequilibrium plasma (APNP) in energy conversion [1][2][3], decontamination [4][5][6], biomedicine [7][8][9][10], materials [11,12], etc. In practical applications, in order to improve the processing efficiency, it is of great significance to generate large-area uniform plasmas.…”

Section: Introductionmentioning

confidence: 99%

A novel flexible plasma array for large-area uniform treatment of an irregular surface

LIU¹,

Qi²,

Zhou³

et al. 2022

Plasma Sci. Technol.

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In this work, we demonstrate a flexible multi-pin plasma generator with movable electrodes, which can change the shape of the electrode array freely, and then provide a large-area uniform plasma for the treatment of surfaces of different shapes. Discharge characteristics including U–I waveforms and discharge images and sterilization performance under three different electrode configurations (flat–flat, flat–curve, curve–curve) are investigated. Very similar results are acquired between the flat–flat configuration and the curve–curve configuration, which is much better than that under flat–curve configuration. This flexible multi-pin plasma generator offers a simple method to treat different irregularly shaped surfaces uniformly with a single device. Moreover, this device provides a foundation for developing a self-adaption large-scale uniform plasma generator by further introducing automatic adjustment of the position of every electrode driven by motors with discharge current feedback in the following study. Thus it will promote the applications of atmospheric-pressure cold plasmas significantly.

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Effect of a non-thermal atmospheric pressure plasma jet on four different yeasts

Cited by 7 publications

References 40 publications

Advancements in Cold Atmospheric Plasma for Skin Disease Treatment and Skincare: A Brief Update

Advancements in Cold Atmospheric Plasma for Skin Disease Treatment and Skincare: A Brief Update

Cold plasma for microbial safety: Principle, mechanism, and factors responsible

A novel flexible plasma array for large-area uniform treatment of an irregular surface

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