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Plasma Medicine

Publicou 4 edições por ano

ISSN Imprimir: 1947-5764

ISSN On-line: 1947-5772

SJR: 0.216 SNIP: 0.263 CiteScore™:: 1.4 H-Index: 24

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Optical and Electrical Characteristics of an Endoscopic DBD Plasma Jet

Volume 10, Edição 2, 2020, pp. 71-90
DOI: 10.1615/PlasmaMed.2020034526
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RESUMO

In this work, a new cold plasma source design capable of generating and transporting a plasma jet over long distances (2 m) is presented with the purpose of being used in flexible endoscopy for treatment within the gastrointestinal tract. This dielectric barrier discharge helium plasma jet consists of a polytetrafluoroethylene capillary connected to a quartz chamber around which a copper electrode is wrapped. A copper wire is freely inserted inside the capillary. The applied voltage is a conventional AC 18-kHz signal to drive the discharge. In order to develop a safe and predictable treatment, a robust and reliable electrical model is necessary and we hypothesized that plasma transport can be modeled as a transmission line. We therefore assessed the electrical behavior of our new cold plasma source. As it is known that the target to which the plasma jet is applied drastically changes the behavior of the plasma itself, an electrical substitute simulating the impedance of a human body is introduced into the circuit, and the plasma behavior is then compared to the free-jet configuration. The effects of the input power (from 10 W to 80 W), and the length of the jet (from 60 cm to 220 cm) were investigated, as well as the electrical changes induced by the presence of an endoscope. The results obtained show trend curves similar to our hypothetical model, although the latter is still only qualitative. This long plasma jet model represents a promising approach that can be used, after further refinement, for controllability of plasma jets for endoscopy applications.

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CITADO POR
  1. Thulliez Max, Bastin Orianne, Nonclercq Antoine, Delchambre Alain, Reniers François, Gel models to assess distribution and diffusion of reactive species from cold atmospheric plasma: an overview for plasma medicine applications, Journal of Physics D: Applied Physics, 54, 46, 2021. Crossref

  2. Corbella Carles, Portal Sabine, Flexible plasma multi-jet source operated in radial discharge configuration, Review of Scientific Instruments, 92, 12, 2021. Crossref

  3. Hadefi Alia, Leprovots Morgane, Thulliez Max, Bastin Orianne, Lefort Anne, Libert Frédérick, Nonclercq Antoine, Delchambre Alain, Reniers François, Devière Jacques, Garcia Marie-Isabelle, Cold atmospheric plasma differentially affects cell renewal and differentiation of stem cells and APC-deficient-derived tumor cells in intestinal organoids, Cell Death Discovery, 8, 1, 2022. Crossref

  4. Miebach Lea, Poschkamp Broder, van der Linde Julia, Bekeschus Sander, Medical Gas Plasma—A Potent ROS-Generating Technology for Managing Intraoperative Bleeding Complications, Applied Sciences, 12, 8, 2022. Crossref

  5. Bastin Orianne, Thulliez Max, Delchambre Alain, Devière Jacques, Reniers François, Nonclercq Antoine, Analysis of a nano-pulsed DBD Plasma jet for endoscopy and impact of excitation parameters, Journal of Physics D: Applied Physics, 55, 41, 2022. Crossref

  6. Thulliez Max, Bastin Orianne, Remy Antoine, Nonclercq Antoine, Devière Jacques, Delchambre Alain, Reniers François, Effect of gas flow on a helium/oxygen endoscopic plasma jet, Journal of Physics D: Applied Physics, 55, 41, 2022. Crossref

  7. Decauchy Henri, Pavy Allan, Camus Marine, Fouassier Laura, Dufour Thierry, Cold plasma endoscopy applied to biliary ducts: feasibility risk assessment on human-like and porcine models for the treatment of cholangiocarcinoma, Journal of Physics D: Applied Physics, 55, 45, 2022. Crossref

  8. Nascimento Fellype do, Leal Bruno Silva, Quade Antje, Kostov Konstantin Georgiev, Different Radial Modification Profiles Observed on APPJ-Treated Polypropylene Surfaces according to the Distance between Plasma Outlet and Target, Polymers, 14, 21, 2022. Crossref

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