RT Journal Article SR Electronic T1 The Application of a Low-temperature Physical Plasma Device Operating Under Atmospheric Pressure Leads to the Production of Toxic NO2 JF Anticancer Research JO Anticancer Res FD International Institute of Anticancer Research SP 2591 OP 2599 DO 10.21873/anticanres.14230 VO 40 IS 5 A1 KARSTEN KLETSCHKUS A1 LYUBOMIR HARALAMBIEV A1 ANDREAS NITSCH A1 FELIX PFISTER A1 GERD KLINKMANN A1 AXEL KRAMER A1 SANDER BEKESCHUS A1 ALEXANDER MUSTEA A1 MATTHIAS B. STOPE YR 2020 UL http://ar.iiarjournals.org/content/40/5/2591.abstract AB Background: Physical plasma is a mixture of reactive particles and electromagnetic radiation. Due to the antimicrobial, immunomodulatory, anti-inflammatory, wound-healing promoting, and antineoplastic effects of body tempered physical plasma under atmospheric pressure (cold atmospheric plasma: CAP), CAP therapy is increasingly becoming the focus of surgical and oncological disciplines. However, when applied in practice, a potential emission of harmful noxae such as toxic nitrogen oxides must be taken into account, which was investigated in the following study. Materials and Methods: MiniJet-R Ar CAP device was characterized with respect to NOX-specific spectra, ultraviolet radiation C (UVC) intensity in the range of 200-275 nm and the formation of NOX gases. Instrument-specific parameters such as gas flow, energy setting of the high-frequency generator, and flow rate of the carrier gas Ar were varied. To test the toxic properties of the NO2 concentrations formed by CAP, SK-OV-3 human ovarian cancer cells were incubated with different NO2 concentrations and cell growth was monitored for 120 h. Results: The operation of MiniJet-R led to the formation of NO2 in the proximity of the CAP effluent. Synthesis of NO led to a NO-specific spectrum in the range of 100-275 nm, whereby UVC radiation produced reached intensities of up to 90 mW/m2. NO gas itself, however, was not detectable, as it was converted to NO2 rapidly. Cell culture incubation experiments demonstrated that NO2 in these concentration ranges had no influence on the cell growth of human cancer cells. Conclusion: Although no limit values were exceeded in the present study, the emission of high-energy UVC radiation and toxic NO2 is a risk factor with regard to the legal regulations on workplace protection (operator hazard) and the approval of medical devices (patient hazard). This is important for considerations regarding treatment frequency and duration. The growth inhibitory effect of CAP treatment on human cancer cells principally suggests a medical application of the MiniJet-R device, although more extensive studies will have to follow.