Supply Systems of Non-Thermal Plasma Reactors. Construction Review with Examples of Applications

Stryczewska, Henryka Danuta

doi:10.3390/app10093242

Cited by 19 publications

(17 citation statements)

References 39 publications

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“…Among the atmospheric cold plasma devices, the dielectric barrier discharge (DBD), plasma jet, gliding arc discharge (GAD), and corona discharge are the most extensively studied (Bermudez-Aguirre 2019 ; Stryczewska 2020 ). DBD is consisted of two parallel metal electrodes which are coated with dielectric materials such as quartz, polymer, or plastic.…”

Section: Acp Devicesmentioning

confidence: 99%

Applications of atmospheric cold plasma in agricultural, medical, and bioprocessing industries

Lin

Khumsupan

Chou

et al. 2022

Appl Microbiol Biotechnol

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Atmospheric cold plasma (ACP) is a nonthermal technology that is extensively used in several industries. Within the scopes of engineering and biotechnology, some notable applications of ACP include waste management, material modification, medicine, and agriculture. Notwithstanding numerous applications, ACP still encounters a number of challenges such as diverse types of plasma generators and sizes, causing standardization challenges. This review focuses on the uses of ACP in engineering and biotechnology sectors in which the innovation can positively impact the operation process, enhance safety, and reduce cost. Additionally, its limitations are examined. Since ACP is still in its nascent stage, the review will also propose potential research opportunities that can help scientists gain more insights on the technology. Key points • ACP technology has been used in agriculture, medical, and bioprocessing industries. • Chemical study on the reactive species is crucial to produce function-specific ACP. • Different ACP devices and conditions still pose standardization problems.

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Section: Acp Devicesmentioning

confidence: 99%

Applications of atmospheric cold plasma in agricultural, medical, and bioprocessing industries

Lin

Khumsupan

Chou

et al. 2022

Appl Microbiol Biotechnol

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“…Los hermanos Siemens-Werner y William comenzaron con las aplicaciones industriales de la descarga eléctrica de plasma, quienes construyeron el primer ozonizador (1857) y el horno de arco eléctrico (1878). Posteriormente, a principios del siglo XX, primero en Niza (1907) y luego en San Petersburgo (1908), los reactores de plasma con descargas de barrera se introdujeron en la tecnología de tratamiento de agua potable (Stryczewska, 2020). En la actualidad, el plasma no térmico o "frío" ha sido ampliamente estudiado en varias áreas de la ciencia y la tecnología como, por ejemplo: En agricultura, para incentivar el crecimiento de plantas e incentivar la germinación; en la ciencia de los alimentos, para modificar sus propiedades, disipar pesticidas, inactivar enzimas y microorganismos; en medicina, para sanar heridas y tratar el cáncer; en electrónica, para generar iluminación y paneles de visualización (pantallas de equipos, televisores, etc.…”

Section: Aplicaciones Del Plasma Frío Atmosféricounclassified

Plasma frío atmosférico para el control de microorganismos patógenos en sistemas agroalimentarios

Muñoz¹,

Concha-Meyer²

2022

Agro sur

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El plasma frío atmosférico (PFA) ha generado gran interés en el área industrial y en la comunidad científica, puesto que presenta valiosas propiedades, como lo son su simplicidad operativa, su bajo costo de funcionamiento, y su respeto por el medio ambiente. El PFA se puede generar a partir de varios gases (aire, nitrógeno, helio, argón) y por diferentes métodos. Sus aplicaciones abarcan múltiples áreas, como medicina, electrónica, ciencia de alimentos y agricultura, entre otros. Una de las principales características del PFA, es su capacidad de eliminar microorganismos patógenos, a través de la generación de radicales libres, los cuales disrumpen las membranas de las células y generan su apoptosis. Debido a esto, diversos investigadores han determinado los efectos de tratamientos con PFA sobre diferentes productos alimentarios, de origen vegetal y animal, contaminados con microorganismos patógenos. En general, se ha encontrado que PFA reduce significativamente la carga microbiológica de diferentes alimentos, sin afectar en la mayoría de los casos sus propiedades nutricionales y calidad. Lo que demuestra que el PFA es una herramienta innovadora y eficaz en la utilización para la inactivación de microorganismos en productos alimentarios.

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“…In thermal plasma, the temperatures of gas molecules and free electrons are approximately identical, whereas in non-thermal plasma, free electrons have a temperature of several electron volts, while the overall gas temperature is close to or slightly above room temperature. Moreover, non-thermal plasma can be generated at both low and atmospheric pressure (Palma et al 2020 ; Stryczewska 2020 ).…”

Section: Fabrication Of Aerosol-based Nanocompositesmentioning

confidence: 99%

Fabrication of aerosol-based nanoparticles and their applications in biomedical fields

Gautam

Kim

Yong

2021

J. Pharm. Investig.

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Background Traditionally, nanoparticles for biomedical applications have been produced via the classical wet chemistry method, with size control remaining a major problem in drug delivery. In recent years, advances in aerosol-based technologies have led to the development of methods that enable the production of nanosized particles and have opened up new opportunities in the field of nano-drug delivery and biomedicine. Aerosol-based technologies have been constantly used to synthesize multifunctional nanoparticles with different properties, which extends their possible biological and medicinal applications. Moreover, aerosol technologies are often more beneficial than other existing approaches because of the major disadvantages of these other techniques. Area covered This review provides a brief discussion of the existing aerosol-based nanotechnologies and applications of nanoparticles in a variety of diseases. Various types of nanoparticles, such as graphene oxide, Prussian blue, black phosphorous, gold, copper, silver, tellurium, iron oxide, titania, magnesium oxide, and zinc oxide nanoparticles, prepared using aerosol technologies are discussed in this review. The different tactics used for surface modifications are also outlined. The biomedical applications of nanoparticles in chemotherapy, bacterial/fungal/viral treatment, disease diagnosis, and biological assays are also presented in this review. Expert opinion Aerosol-based technologies can be used to design nanoparticles with the desired functionality. This significantly benefits the nanomedicine field, particularly as product parameters are becoming more encompassing and exacting. One of the biggest issues with conventional methods is their scale-up/scale-down and clinical translation. Aerosol-based nanoparticle synthesis helps enhance control over the product properties and facilitate their use for clinical applications.

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Supply Systems of Non-Thermal Plasma Reactors. Construction Review with Examples of Applications

Cited by 19 publications

References 39 publications

Applications of atmospheric cold plasma in agricultural, medical, and bioprocessing industries

Applications of atmospheric cold plasma in agricultural, medical, and bioprocessing industries

Plasma frío atmosférico para el control de microorganismos patógenos en sistemas agroalimentarios

Fabrication of aerosol-based nanoparticles and their applications in biomedical fields

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