อิทธิพลของพลาสมาเย็นต่อเซลล์มะเร็งในโครงเลี้ยงเซลล์แบบสามมิติจากวัสดุชีวภาพ Impact of Plasma Treatment on Cancer Cell Culture in 3D Biomaterial Scaffold

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Published: Jan 9, 2018
Keywords:
โครงเลี้ยงเซลล์ ไฟโบรอิน ไคโตซาน พลาสมาเย็น มะเร็งกระดูกอ่อน มะเร็ง เทคนิคการทำแห้งแบบเยือกแข็ง การออกแบบการทดลองแบบแฟกทอเรียล Scaffold Fibroin Chitosan Cold Plasma Technology Cancer Freeze Drying Technique Chondrosarcomar Cells Full factorial design with center points, Design of Experiment

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Kochakon Moonsub
Advanced Manufacturing Technology Research Center (AMTech), Department of Industrial 1)Engineering, Faculty of Engineering, Chiang Mai University, Chiang Mai 50200, Thailand. 2)Biomedical Engineering Center (BMEC), Chiang Mai University, Chiang Mai 50200, Thailand

Abstract

Cancer is one of three major causes of death around the world. There are several techniques for cancer treatment. Nevertheless, most current treatments cause severe side effects to the patient. Recently, Cold Plasma technology has been introduced and implemented as a tumor and cancer therapy in mammalian cells. Several studies showed the benefit of Cold Plasma on cancer cell death induction without damaging neighboring normal cells. However, the Cold Plasma treatment conditions such as plasma power, gas, and time for properly treat the infected cell has not been clearly defined. In this study, investigation of Cold Plasma treatment on cancer cell will be performed based on tissue engineering approach. Three dimension scaffold plays an important role on the structure and biological mimic condition for cell adhesion and proliferation. This biomaterial 3D scaffold was fabricated from fibroin and chitosan using freeze drying technique, which then will be cultured with chondrosarcomar cells (cartilage cancer cells) incubated at 37ºC 5% CO2 for 1 day for the investigation. Then, the treatment of Cold Plasma with various conditions of electrical plasma power, percentage of O2 mixed gas, and duration will be investigated based on Factorial Experimental Design. Consequently, the survival cell percentage  after Cold Plasma treatments will be determined by MTT assay. Finally, the results of survival cell percentage show that the condition of 30 s. treatment time, 30 ml/min O2 with Argon and 30 Watt power causes the lowest cell viability of 83.33 percentage


 

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How to Cite
Moonsub, K. (2018). อิทธิพลของพลาสมาเย็นต่อเซลล์มะเร็งในโครงเลี้ยงเซลล์แบบสามมิติจากวัสดุชีวภาพ: Impact of Plasma Treatment on Cancer Cell Culture in 3D Biomaterial Scaffold. Naresuan University Engineering Journal, 12(2), 111–120. Retrieved from https://ph01.tci-thaijo.org/index.php/nuej/article/view/79371
Issue
Vol. 12 No. 2 (2017): July - December
Section
Research Paper
Author Biography

Kochakon Moonsub, Advanced Manufacturing Technology Research Center (AMTech), Department of Industrial 1)Engineering, Faculty of Engineering, Chiang Mai University, Chiang Mai 50200, Thailand. 2)Biomedical Engineering Center (BMEC), Chiang Mai University, Chiang Mai 50200, Thailand

Department of Industrial Engineering, Faculty of Engineering, Chiang Mai University

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