Atmospheric pressure DC-driven self-pulsing transient spark (TS) discharge operated in air and pulse-driven dielectric barrier discharge plasma jet (PJ) operated in helium in contact with water solutions were used for inducing chemical effects in water solutions, and the treatment of bacteria (Escherichia coli), mammalian cells (Vero line normal cells, HeLa line cancerous cells), deoxyribonucleic acid (dsDNA), and protein (bovine serum albumin). Two different methods of water solution supply were used in the TS: water electrode system and water spray system. The effects of both TS systems and the PJ were compared, as well as a direct exposure of the solution to the discharge with an indirect exposure to the discharge activated gas flow. The chemical analysis of water solutions was performed by using colorimetric methods of UV-VIS absorption spectrophotometry. The bactericidal effects of the discharges on bacteria were evaluated by standard microbiological plate count method. Viability, apoptosis and cell cycle were assessed in normal and cancerous cells. Viability of cells was evaluated by trypan blue exclusion test, apoptosis by Annexin V-FITC/propidium iodide assay, and cell cycle progression by propidium iodide/RNase test. The effect of the discharges on deoxyribonucleic acid and protein were evaluated by fluorescence and UV absorption spectroscopy. The results of bacterial and mammalian cell viability, apoptosis, and cell cycle clearly show that cold plasma can inactivate bacteria and selectively target cancerous cells, which is very important for possible future development of new plasma therapeutic strategies in biomedicine. The authors found that all investigated bio-effects were stronger with the air TS discharge than with the He PJ, even in indirect exposure.
References
1.
2.
Plasma for Bio-Decontamination, Medicine and Food Security, NATO Science for Peace and Security Series A: Chemistry and Biology
, edited by Z.
Machala
, K.
Hensel
, and Y.
Akishev
(Springer
, New York
, 2012
).3.
Th.
von Woedtke
, S.
Reuter
, K.
Masur
, and K.-D.
Weltmann
, Phys. Rep.
530
, 291
(2013
).4.
Plasma Medicine: Applications of Low-Temperature Gas Plasmas in Medicine and Biology
, edited by M.
Laroussi
(Cambridge University
, Cambridge
, 2012
).5.
S.
Kalghatgi
, C. M.
Kelly
, F.
Cerchar
, B.
Torabi
, O.
Alekseev
, and A.
Fridman
, PLoS One
6
, e16270
(2011
).6.
E.
Stoffels
, I. E.
Kieft
, and R. E. J.
Sladek
, J. Phys. D: Appl. Phys.
36
, 2908
(2003
).7.
I. E.
Kieft
, M.
Kurdi
, and E.
Stoffels
, IEEE Trans. Plasma Sci.
34
, 1331
(2006
).8.
C. A.
Schmitt
and S. W.
Lowe
, J. Pathol.
187
, 127
(1999
).9.
S. J.
Kim
, T. H.
Chung
, S. H.
Bae
, and S. H.
Leem
, Appl. Phys. Lett.
97
, 023702
(2010
).10.
J. Y.
Kim
, J.
Ballato
, P.
Foy
, T.
Hawkins
, Y.
Wei
, J.
Li
, and S.
Kim
, Biosens. Bioelectron.
28
, 333
(2011
).11.
M.
Keidar
, R.
Walk
, A.
Shashurin
, P.
Srinivasan
, A.
Sandler
, S.
Dasgupta
, R.
Ravi
, R.
Guerrero-Preston
, and B.
Trink
, Br. J. Cancer
105
, 1295
(2011
).12.
L. I.
Partecke
et al., BMC Cancer
12
, 473
(2012
).13.
O.
Kylian
, M.
Hasiwa
, D.
Gilliland
, and F.
Rossi
, Plasma Processes Polym.
5
, 26
(2008
).14.
Z.
Machala
, L.
Chládeková
, and M.
Pelach
, J. Phys. D: Appl. Phys.
43
, 222001
(2010
).15.
T. T.
Chung
, N.
Ning
, J. W.
Chu
, D. B.
Graves
, E.
Bartis
, J.
Seog
, and G. S.
Oehrlein
, Plasma Processes Polym.
10
, 167
(2013
).16.
J.-W.
Lackmann
, E.
Edengeiser
, S.
Schneider
, J.
Benedikt
, M.
Havenith
, and J. E.
Bandow
, Plasma Med.
3
, 115
(2013
).17.
O.
Kylian
, H.
Rauscher
, D.
Gilliland
, F.
Bretagnol
, and F.
Rossi
, J. Phys. D: Appl. Phys.
41
, 095201
(2008
).18.
C.
Bernard
, A.
Leduc
, J.
Barbeau
, B.
Saoudi
, L. H.
Yahia
, and G.
De Crescenzo
, J. Phys. D: Appl. Phys.
39
, 3470
(2006
).19.
E.
Takai
, K.
Kitano
, J.
Kuwabara
, and K.
Shiraki
, Plasma Processes Polym.
9
, 77
(2012
).20.
E.
Takai
, T.
Kitamura
, J.
Kuwabara
, S.
Ikawa
, S.
Yoshizawa
, K.
Shiraki
, H.
Kawasaki
, R.
Arakawa
, and K.
Kitano
, J. Phys. D: Appl. Phys.
47
, 285403
(2014
).21.
X. T.
Deng
, J. J.
Shi
, and M. G.
Kong
, J. Appl. Phys.
101
, 074701
(2007
).22.
A.
Mizuno
and S.
Katsura
, J. Biol. Phys.
28
, 587
(2002
).23.
S.
Lazović
, D.
Maletić
, A.
Leskovac
, J.
Filipović
, N.
Puać
, G.
Malović
, G.
Joksić
, and Z. Lj.
Petrović
, Appl. Phys. Lett.
105
, 124101
(2014
).24.
X.
Han
, W. A.
Cantrell
, E. E.
Escobar
, and S.
Ptasinska
, Eur. Phys. J. D
68
, 46
(2014
).25.
D.
O'Connell
, L. J.
Cox
, W. B.
Hyland
, S. J.
McMahon
, S.
Reuter
, W. G.
Graham
, T.
Gans
, and F. J.
Currell
, Appl. Phys. Lett.
98
, 043701
(2011
).26.
27.
D. B.
Graves
, Plasma Processes Polym.
11
, 1120
(2014
).28.
S.
Arndt
, E.
Wacker
, Y.
Li
, T.
Shimizu
, H.
Thomas
, G.
Morfill
, S.
Karrer
, J.
Zimmermann
, and A.
Bosserhoff
, Exp. Dermatol.
22
, 284
(2013
).29.
J.
Chang
et al., PLoS One
9
, e92198
(2014
).30.
S.
Kalghatgi
et al., “Mechanism of Induction of Apoptosis in Melanoma Cancer Cells by Non-Thermal Plasma
,” in 36th IEEE International Conference on Plasma Science (ICOPS)
, San Diego, CA, 29th May–4th Jun 2009
(IEEE
).31.
K.
Ninomiya
, T.
Ishijima
, M.
Imamura
, T.
Yamahara
, H.
Enomoto
, K.
Takahashi
, Y.
Tanaka
, Y.
Uesugi
, and N.
Shimizu
, J. Phys. D: Appl. Phys.
46
, 425401
(2013
).32.
M.
Thiyagarajan
, H.
Anderson
, and X. F.
Gonzales
, Biotechnol. Bioeng.
111
, 565
(2014
).33.
O.
Volotskova
, T. S.
Hawley
, M. A.
Stepp
, and M.
Keidar
, Sci. Rep.
2
, 636
(2012
).34.
X.
Yan
et al., IEEE Trans. Plasma Sci.
38
, 2451
(2010
).35.
Y.
Ma
, C. S.
Ha
, S. W.
Hwang
, H. J.
Lee
, G. C.
Kim
, K. W.
Lee
, and K.
Song
, PLoS One
9
, e91947
(2014
).36.
R.
Guerrero-Preston
et al., Int. J. Mol. Med.
34
, 941
(2014
).37.
M.
Keidar
, A.
Shashurin
, O.
Volotskova
, M. A.
Stepp
, P.
Srinivasan
, A.
Sandler
, and B.
Trink
, Phys. Plasmas
20
, 057101
(2013
).38.
W.
Murphy
, C.
Carroll
, and M.
Keidar
, J. Phys. D: Appl. Phys.
47
, 472001
(2014
).39.
M.
Naciri
, D.
Dowling
, and M.
Al-Rubeai
, Plasma Processes Polym.
11
, 391
(2014
).40.
M. G.
Kong
, M.
Keidar
, and K.
Ostrikov
, J. Phys. D: Appl. Phys.
44
, 174018
(2011
).41.
V.
Miller
, A.
Lin
, G.
Fridman
, D.
Dobrynin
, and A.
Fridman
, Plasma Processes Polym.
11
, 1193
(2014
).42.
G.
Collet
, E.
Robert
, A.
Lenoir
, M.
Vandamme
, T.
Darny
, S.
Dozias
, C.
Kieda
, and J.-M.
Pouvesle
, Plasma Sources Sci. Technol.
23
, 012005
(2014
).43.
J.
Schlegel
, J.
Koritzer
, and V.
Boxhammer
, Clin. Plasma Med.
1
, 2
(2013
).44.
X.
Cheng
et al., J. Phys. D: Appl. Phys.
47
, 335402
(2014
).45.
L.
Brullé
et al., PLoS One
7
, e52653
(2012
).46.
J. S.
Chang
, P. A.
Lawless
, and T.
Yamamoto
, IEEE Trans. Plasma Sci.
19
, 1152
(1991
).47.
U.
Kogelschatz
, Plasma Chem. Plasma Process.
23
, 1
(2003
).48.
D. B.
Graves
, J. Phys. D: Appl. Phys.
45
, 263001
(2012
).49.
D. B.
Graves
, Clin. Plasma Med.
2
, 38
(2014
).50.
M.
Naitali
, J.-M.
Herry
, E.
Hnatiuc
, G.
Kamgang
, and J.-L.
Brisset
, Plasma Chem. Plasma Process.
32
, 675
(2012
).51.
M. J.
Traylor
, M. J.
Pavlovich
, S.
Karim
, P.
Hait
, Y.
Sakiyama
, D. S.
Clark
, and D. B.
Graves
, J. Phys. D: Appl. Phys.
44
, 472001
(2011
).52.
T. A.
Reiter
, Redox Rep.
11
, 194
(2006
).53.
E.
Marode
, A.
Goldman
, and M.
Goldman
, High pressure discharge as a trigger for pollution control in Non-Thermal Plasma Techniques for Pollution Control
, NATO ASI Series, Part A, edited by B. M.
Penetrante
and S. E.
Schultheis
(Springer
, New York
, 1993
), pp. 167
–190
.54.
R.
Morrow
and J. J.
Lowke
, J. Phys. D: Appl. Phys.
30
, 614
(1997
).55.
Z.
Machala
, M.
Morvová
, E.
Marode
, and I.
Morva
, J. Phys. D: Appl. Phys.
33
, 3198
(2000
).56.
X.
Lu
, M.
Laroussi
, and V.
Puech
, Plasma Sources Sci. Technol.
21
, 034005
(2012
).57.
E.
Robert
et al., Clin. Plasma Med.
1
, 8
(2013
).58.
Z.
Xiong
, E.
Robert
, V.
Sarron
, J.-M.
Pouvesle
, and M. J.
Kushner
, J. Phys. D: Appl. Phys.
46
, 155203
(2013
).59.
F.
Pechereau
, J.
Jánský
, and A.
Bourdon
, Plasma Sources Sci. Technol.
21
, 055011
(2012
).60.
S.
Lazović
et al., New J. Phys.
12
, 083037
(2010
).61.
X.
Yan
, Z. L.
Xiong
, F.
Zou
, S. S.
Zhao
, X. P.
Lu
, G. X.
Yang
, G. Y.
He
, and K.
Ostrikov
, Plasma Processes Polym.
9
, 59
(2012
).62.
J.
Heinlin
, G.
Morfill
, M.
Landthaler
, W.
Stolz
, G.
Isbary
, J. L.
Zimmermann
, T.
Shimizu
, and S.
Karrer
, J. Dtsch. Dermatol. Ges.
8
, 968
(2010
).63.
K.-D.
Weltmann
, K.
Fricke
, M.
Stieber
, R.
Brandenburg
, T.
von Woedtke
, and U.
Schnabel
, IEEE Trans. Plasma Sci.
40
, 2963
(2012
).64.
A.
Nastuta
, V.
Pohoata
, and I.
Topala
, J. Appl. Phys.
113
, 183302
(2013
).65.
J.
Lademann
et al., J. Biomed. Opt.
14
, 054025
(2009
).66.
M.
Vandamme
et al., Int. J. Cancer
130
, 2185
(2012
).67.
F.
Utsumi
et al., PLoS One
8
, e81576
(2013
).68.
J. Y.
Kim
, S. O.
Kim
, Y. Z.
Wei
, and J. H.
Li
, Appl. Phys. Lett.
96
, 203701
(2010
).69.
M.
Janda
, V.
Martišovitš
, and Z.
Machala
, Plasma Sources Sci. Technol.
20
, 035015
(2011
).70.
M.
Janda
, Z.
Machala
, A.
Niklová
, and V.
Martišovitš
, Plasma Sources Sci. Technol.
21
, 045006
(2012
).71.
Z.
Machala
, B.
Tarabová
, K.
Hensel
, E.
Špetliková
, L.
Šikurová
, and P.
Lukeš
, Plasma Processes Polym.
10
, 649
(2013
).72.
W.
Strober
, Current Protocols in Immunology
(Wiley
, New York
, 2001
), 21:3B:A.3B.1–A.3B.2.73.
Z.
Machala
, M.
Janda
, K.
Hensel
, I.
Jedlovský
, L.
Leštinská
, V.
Foltin
, V.
Martišovitš
, and M.
Morvová
, J. Mol. Spectrosc.
243
, 194
(2007
).74.
M.
Janda
, V.
Martišovitš
, K.
Hensel
, L.
Dvonč
, and Z.
Machala
, Plasma Sources Sci. Technol.
23
, 065016
(2014
).75.
I.
Topala
, N.
Dumitrascu
, and D. G.
Dimitriu
, IEEE Trans. Plasma Sci.
40
, 2811
(2012
).76.
A. V.
Nastuta
, I.
Topala
, C.
Grigoras
, V.
Pohoata
, and G.
Popa
, J. Phys. D: Appl. Phys.
44
, 105204
(2011
).77.
R.
Jijie
, V.
Pohoata
, and I.
Topala
, Appl. Phys. Lett.
101
, 144103
(2012
).78.
M.
Wertheimer
, M.
Ahlawat
, B.
Saoudi
, and R.
Kashyap
, Appl. Phys. Lett.
100
, 201112
(2012
).79.
I.
Topala
and M.
Nagastu
, Appl. Phys. Lett.
106
, 054105
(2015
).80.
P.
Lukeš
, E.
Doležalová
, I.
Sisrová
, and M.
Člupek
, Plasma Sources Sci. Technol.
23
, 015019
(2014
).81.
J.-L.
Brisset
and E.
Hnatiuc
, Plasma Chem. Plasma Process.
32
, 655
(2012
).82.
S.
Giglio
, P. T.
Monis
, and C. P.
Saint
, Nucleic Acids Res.
31
, e136
(2003
).© 2015 American Vacuum Society.
2015
American Vacuum Society
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