The antiproliferative effects of cold atmospheric plasma‐activated media on different cancer cell lines, the implication of ozone as a possible underlying mechanism

The antiproliferative effects of cold atmospheric plasma‐activated media on different cancer cell lines, the implication of ozone as a possible underlying mechanism

Recent studies have proven several promising anticancer activities for cold atmospheric plasma (CAP) against a wide range of cancer cells in vitro. Recently, media treated with CAP have also found to effectively eradicate cancer cells similar to the CAP. Based on advantages, many researchers prefer...

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Veröffentlicht in:Journal of cellular physiology 2019-05, Vol.234 (5), p.6778-6782
Hauptverfasser: Mokhtari, Hesam, Farahmand, Leila, Yaserian, Kiomars, Jalili, Neda, Majidzadeh‐A, Keivan
Format: Artikel
Sprache:eng
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A549 Cells
Activation
Anticancer properties
Antineoplastic Agents - pharmacology
Antitumor activity
Biotechnology
Cancer
CAP‐activated media
Cell death
Cell Death - drug effects
Cell Line, Tumor
Cell Proliferation - drug effects
cell viability
cold atmospheric plasma
Cytotoxicity
Fibroblasts
Fibroblasts - drug effects
Fibroblasts - metabolism
Humans
MCF-7 Cells
Media
Ozone
Ozone - pharmacology
Plasma Gases - pharmacology
Reactive Oxygen Species - metabolism
Skin
Toxicity
Tumor cell lines
Viability
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container_end_page 6782
container_issue 5
container_start_page 6778
container_title Journal of cellular physiology
container_volume 234
creator Mokhtari, Hesam
Farahmand, Leila
Yaserian, Kiomars
Jalili, Neda
Majidzadeh‐A, Keivan
description Recent studies have proven several promising anticancer activities for cold atmospheric plasma (CAP) against a wide range of cancer cells in vitro. Recently, media treated with CAP have also found to effectively eradicate cancer cells similar to the CAP. Based on advantages, many researchers prefer to apply CAP‐activated media (PAM) as an alternative to cap in the treatment of cancer. However, less has been achieved regarding the anticancer effects and anticancer mechanisms of PAM. Investigating the selective anticancerous activities of PAM, the viability of SKBR3, MCF7, ASPC‐1, A‐549, G‐292, and SW742 cancer cell lines, as well as normal human skin fibroblasts (FMGB‐1) and MCF10A cells in relation to the media activation time, and the length of exposure was studied. Also, we examined the concentration of ozone in media as a function to CAP activation time since recent studies have proposed ozone as a pivotal reactive species in the induction of cell death. Based on the result, both increasing the duration of media activation time and the length of exposure to PAM could significantly increase the anticancer activity. Nevertheless, the cytotoxicity on normal cells was either not affected or slightly increased. Among the six tested cancer cell lines, SW742 was the most resistant and SKBR3 the most susceptible cancer cell lines to PAM. Also, increasing duration of treatment with CAP resulted in a significant rise in O3 concentration levels in media. Overall, these results suggest PAM, as a promising tool in the treatment of different cancers and O 3 formation as a probable underlying mechanism. Recently, media treated with cold atmospheric plasma (CAP) have also found to effectively eradicate cancer cells similar to the CAP. Based on advantages, many researchers prefer to apply CAP‐activated media (PAM) as an alternative to cap in treatment of cancer. However, less has been achieved regarding the anticancer effects and anticancer mechanisms of PAM. Investigating the selective anticancerous activities of PAM, the viability of SKBR3, MCF7, ASPC‐1, A‐549, G‐292, and SW742 cancer cell liness, as well as normal human skin fibroblasts (FMGB‐1) and MCF10A cells in relation to the media activation time, and the length of exposure was studied.
doi_str_mv 10.1002/jcp.27428
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Nevertheless, the cytotoxicity on normal cells was either not affected or slightly increased. Among the six tested cancer cell lines, SW742 was the most resistant and SKBR3 the most susceptible cancer cell lines to PAM. Also, increasing duration of treatment with CAP resulted in a significant rise in O3 concentration levels in media. Overall, these results suggest PAM, as a promising tool in the treatment of different cancers and O 3 formation as a probable underlying mechanism. Recently, media treated with cold atmospheric plasma (CAP) have also found to effectively eradicate cancer cells similar to the CAP. Based on advantages, many researchers prefer to apply CAP‐activated media (PAM) as an alternative to cap in treatment of cancer. However, less has been achieved regarding the anticancer effects and anticancer mechanisms of PAM. Investigating the selective anticancerous activities of PAM, the viability of SKBR3, MCF7, ASPC‐1, A‐549, G‐292, and SW742 cancer cell liness, as well as normal human skin fibroblasts (FMGB‐1) and MCF10A cells in relation to the media activation time, and the length of exposure was studied.</abstract><cop>United States</cop><pub>Wiley Subscription Services, Inc</pub><pmid>30387137</pmid><doi>10.1002/jcp.27428</doi><tpages>5</tpages><orcidid>https://orcid.org/0000-0002-8811-0997</orcidid></addata></record>
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subjects A549 Cells
Activation
Anticancer properties
Antineoplastic Agents - pharmacology
Antitumor activity
Biotechnology
Cancer
CAP‐activated media
Cell death
Cell Death - drug effects
Cell Line, Tumor
Cell Proliferation - drug effects
cell viability
cold atmospheric plasma
Cytotoxicity
Fibroblasts
Fibroblasts - drug effects
Fibroblasts - metabolism
Humans
MCF-7 Cells
Media
Ozone
Ozone - pharmacology
Plasma Gases - pharmacology
Reactive Oxygen Species - metabolism
Skin
Toxicity
Tumor cell lines
Viability
title The antiproliferative effects of cold atmospheric plasma‐activated media on different cancer cell lines, the implication of ozone as a possible underlying mechanism
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