Helium plasma jet interactions with water in well plates

Plasma activation of liquids or cell cultures is a method for investigating the consequences of plasma produced reactive oxygen and nitrogen species (RONS) on living systems. The reproducible transfer of RONS, ions, electrons, and photons to the liquid is critical for determining reaction mechanisms...

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Bibliographic Details
Published in:Plasma processes and polymers 2020-03, Vol.17 (3), p.n/a
Main Authors: Mohades, Soheila, Lietz, Amanda M., Kruszelnicki, Juliusz, Kushner, Mark J.
Format: Article
Language:English
Subjects:
Activation
Aerodynamics
atmospheric pressure plasma jet
biotechnology
Computational fluid dynamics
Fluid flow
Gas flow
Helium plasma
Hydrogen peroxide
In vitro methods and tests
Ionization waves
Jet interaction
modeling and simulation
Plasma
plasma activated liquid
Plasma jets
Reaction mechanisms
Reproducibility
Rims
Vortices
Water vapor
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Summary:Plasma activation of liquids or cell cultures is a method for investigating the consequences of plasma produced reactive oxygen and nitrogen species (RONS) on living systems. The reproducible transfer of RONS, ions, electrons, and photons to the liquid is critical for determining reaction mechanisms and biological outcomes, and depends strongly on system parameters. A common in vitro method of plasma treatment of cells is a plasma jet directed into a well plate filled (or partially filled) with a liquid cell growth media. This method of treatment intrinsically has several environmental and geometrical factors that could lead to variability in the activation of the media. Uncontrolled or unreported geometrical and environmental factors that affect this transfer can, therefore, influence the reproducibility of measurements. In this paper, results from a numerical modeling investigation of a pulsed helium plasma jet interacting with water in a well plate are discussed while varying the height of the well‐plate rim. The height of the rim changes gas flow patterns, the ratio of He‐to‐air, and the water vapor content in the gas layer above the liquid. With a low rim, gas flowing from the jet stagnates on‐axis and flows radially outward with few vortices that recirculate reactants. With high rims, the gas flow is dominated by vortices and recirculation. With a low rim, the ionization wave (IW) from the jet strikes the liquid and proceeds as a surface IW across the water. With higher rims, the densities of helium and water vapor are higher above the liquid, which results in a volumetric propagation of the IW, initially producing higher densities of H2, HO2, OH, and H2O2. The end result is that for otherwise identical conditions, the densities of solvated H2O2aq and select reactive nitrogen species increase with rim height due to the vortices that recirculate reactants. During plasma activation of liquids, the reproducible transfer of reactive species to the liquid is critical. A common in vitro method for treatment of cells is a plasma jet directed into a well plate filled with a liquid cell growth medium. This method has geometrical factors that could lead to variability in activation of the medium. Results from a numerical investigation of a pulsed helium plasma jet interacting with water in a well plate are discussed as a function of the height of the well‐plate rim. The height affects the plasma plume, flow patterns, recirculation of gas from the ambient into
ISSN:1612-8850
1612-8869
DOI:10.1002/ppap.201900179