Modelling the helium plasma jet delivery of reactive species into a 3D cancer tumour

Szili, Endre J. and Oh, Jun Seok and Fukuhara, Hideo and Bhatia, Rishabh and Gaur, Nishtha and Nguyen, Cuong K. and Hong, Sung Ha and Ito, Satsuki and Ogawa, Kotaro and Kawada, Chiaki and Shuin, Taro and Tsuda, Masayuki and Furihata, Mutsuo and Kurabayashi, Atsushi and Furuta, Hiroshi and Ito, Masafumi and Inoue, Keiji and Hatta, Akimitsu and Short, Robert D. (2018) Modelling the helium plasma jet delivery of reactive species into a 3D cancer tumour. Plasma Sources Science and Technology, 27 (1): 014001. ISSN 0963-0252

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Abstract

Cold atmospheric plasmas have attracted significant worldwide attention for their potential beneficial effects in cancer therapy. In order to further improve the effectiveness of plasma in cancer therapy, it is important to understand the generation and transport of plasma reactive species into tissue fluids, tissues and cells, and moreover the rates and depths of delivery, particularly across physical barriers such as skin. In this study, helium (He) plasma jet treatment of a 3D cancer tumour, grown on the back of a live mouse, induced apoptosis within the tumour to a depth of 2.8 mm. The He plasma jet was shown to deliver reactive oxygen species through the unbroken skin barrier before penetrating through the entire depth of the tumour. The depth and rate of transport of He plasma jet generated H2O2, NO3 - and NO2 -, as well as aqueous oxygen [O2(aq)], was then tracked in an agarose tissue model. This provided an approximation of the H2O2, NO3 -, NO2 - and O2(aq) concentrations that might have been generated during the He plasma jet treatment of the 3D tumour. It is proposed that the He plasma jet can induce apoptosis within a tumour by the 'deep' delivery of H2O2, NO3 - and NO2 - coupled with O2(aq); the latter raising oxygen tension in hypoxic tissue.

Item Type:
Journal Article
Journal or Publication Title:
Plasma Sources Science and Technology
Uncontrolled Keywords:
/dk/atira/pure/subjectarea/asjc/3100/3104
Subjects:
?? cancer therapyhyperbaric medicinehypoxiaplasma jetreactive oxygen species (ros) and reactive nitrogen species (rns)tissue modeltissue oxygenationcondensed matter physics ??
ID Code:
135137
Deposited By:
Deposited On:
14 Feb 2020 16:20
Refereed?:
Yes
Published?:
Published
Last Modified:
15 Jul 2024 19:36