等离子体活化介质处理与直接冷等离子体处理有何不同？

How Does Plasma Activated Media Treatment Differ From Direct Cold Plasma Treatment?

作者信息

Attri Pankaj, Park Ji Hoon, Ali Anser, Choi Eun Ha

机构信息

Department of Electrical and Biological Physics, Plasma Bioscience Research Center, Kwangwoon University, Seoul 01897, Korea.

出版信息

Anticancer Agents Med Chem. 2018;18(6):805-814. doi: 10.2174/1871520618666180406121734.

DOI:10.2174/1871520618666180406121734

PMID:29623855

Abstract

OBJECTIVE

The aim of the paper is to investigate the optimum condition for generation of Plasma Activated Media (PAM), where it can deactivate the cancer cells while minimum damage for normal cells.

BACKGROUND

Over past few years, cold atmospheric Plasma-Activated Media (PAM) have shown its promising application in plasma medicine for treatment of cancer. PAM has a tremendous ability for selective anti-cancer capacity in vitro and in vivo.

METHODS

We have analyzed the radicals in air using the optical emission spectroscopy and in culture media using chemical analysis. Further, we have tested the toxicity of PAM using MTT assay.

RESULTS

We observed that more cancer cell death is for the Ar plasma followed by the Ar-N2 plasma, and the least cell death was observed for the Ar-O2 plasma at all treatment times both by direct treatment and through PAM treatment. The concentration of the RNS species is high for Ar-N2 plasma in gas as well as inside the culture media compared to that for pure Ar plasma. However, the difference is significantly less between the Ar plasma treatments and the Ar-N2 plasma treatments, showing that ROS is the main factor contributing to cell death.

CONCLUSION

Among all three feeding gas plasmas the best system is Ar-O2 plasma for direct treatments towards the cancer cells. In addition, the best system for PAM preparation is Ar-N2 at low time treatments (1 min and 2 min) because it has no effect on normal cells, but kills the cancer cells.

摘要

目的

本文旨在研究生成等离子体活化介质（PAM）的最佳条件，使其能够使癌细胞失活，同时对正常细胞造成最小损伤。

背景

在过去几年中，冷大气等离子体活化介质（PAM）在癌症治疗的等离子体医学中显示出其广阔的应用前景。PAM在体外和体内具有巨大的选择性抗癌能力。

方法

我们使用发射光谱法分析了空气中的自由基，并使用化学分析法分析了培养基中的自由基。此外，我们使用MTT法测试了PAM的毒性。

结果

我们观察到，在所有处理时间，无论是直接处理还是通过PAM处理，氩等离子体处理后的癌细胞死亡数量最多，其次是氩 - 氮等离子体，氩 - 氧等离子体处理后的细胞死亡数量最少。与纯氩等离子体相比，氩 - 氮等离子体在气体以及培养基中的活性氮物质浓度更高。然而，氩等离子体处理和氩 - 氮等离子体处理之间的差异明显较小，表明活性氧是导致细胞死亡的主要因素。

结论

在所有三种供气等离子体中，对于直接处理癌细胞而言，最佳体系是氩 - 氧等离子体。此外，在短时间处理（1分钟和2分钟）时，制备PAM的最佳体系是氩 - 氮等离子体，因为它对正常细胞没有影响，但能杀死癌细胞。

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等离子体活化介质处理与直接冷等离子体处理有何不同？

How Does Plasma Activated Media Treatment Differ From Direct Cold Plasma Treatment?

作者信息

机构信息

出版信息

OBJECTIVE

BACKGROUND

METHODS

RESULTS

CONCLUSION

目的

背景

方法

结果

结论

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