Abstract
The need for effective and safe therapies for cancer is growing as aging is modifying its epidemiology. Cold atmospheric plasma (CAP) has gained attention as a potential anti-tumor therapy. CAP is a gas with enough energy to ionize a significant fraction of its constituent particles, forming equal numbers of positive ions and electrons. Timely-resolved output voltage measurement, emission spectroscopy, and quantification of reactive species (RS) in plasma-activated media (PAM) were performed to characterize the physical and chemical properties of plasma. To assess the cytotoxicity of cold atmospheric plasma in human tumors, different cell lines were cultured, plated, and exposed to CAP, followed by MTT and SRB colorimetric assays 24 h later. Human fibroblasts, phenotypically normal cells, were processed similarly. Plasma cytotoxicity was higher in cells of breast cancer, urinary bladder cancer, osteosarcoma, lung cancer, melanoma, and endometrial cancer. Cytotoxicity was time-dependent and possibly related to the increased production of hydrogen peroxide in the exposed medium. Sixty seconds of CAP exposure renders selective effects, preserving the viability of fibroblast cells. These results point to the importance of conducting further studies of the therapy with plasma.
Highlights
Normal cells evolve progressively to neoplastic cells as they develop a succession of capabilities, named the hallmarks of cancer
[55,56].InInorder orderto toenable enable precise precise targeting completely understood targetingofoftumor tumorcells, cells,we we developed an air plasma jet based on a high-voltage sharply-pointed electrode
Plasma is produced according to a point-to-plane pulsed corona discharge model
Summary
Normal cells evolve progressively to neoplastic cells as they develop a succession of capabilities, named the hallmarks of cancer. It is reasonable to assume that the density for these two types of plasma is approximately equal to the atmospheric density, but for atmospheric pressure plasmas, the mean free paths separating electrons and heavy particles are shorter than those from low-pressure plasmas; the former is essentially governed by collisions among particles [3] Under such conditions, local thermodynamic equilibrium (LTE) tends to prevail including kinetic equilibrium, meaning that electrons and heavier particles may have similar energy (the temperature of electrons, Te , is similar to the temperature of heavier particles, Th , or the sensible temperature defined as the temperature of non-ion species), and chemical equilibrium when different ions species are presented. By passing an electric current through an ionized gas, a process, known as gaseous discharge takes place, and plasma is produced [4]
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