Microfluidic concentration gradient for toxicity studies of lung carcinoma cells

Cancer is a serious global health problem, which resulted in 8.2 million deaths in 2012 alone. Amongst different types of cancer, lung cancer is the most lethal and contributes 19.4% of cancer deaths. Better disease-free cancer survival rates have been reported when surgery is followed by systemic c...

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Main Authors: Zaidon, Nuradawiyah, Mohd Mansor, Ahmad Fairuzabadi, Wing, Cheung Mak, Ismail, Ahmad Faris, Nordin, Anis Nurashikin
Format: Article
Language:English
Published: Elsevier 2017
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Online Access:http://irep.iium.edu.my/57788/1/1-s2.0-S2212017317300683-main.pdf
http://irep.iium.edu.my/57788/
http://www.sciencedirect.com/science/article/pii/S2212017317300683
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Institution: Universiti Islam Antarabangsa Malaysia
Language: English
id my.iium.irep.57788
record_format dspace
institution Universiti Islam Antarabangsa Malaysia
building IIUM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider International Islamic University Malaysia
content_source IIUM Repository (IREP)
url_provider http://irep.iium.edu.my/
language English
topic TK7800 Electronics. Computer engineering. Computer hardware. Photoelectronic devices
spellingShingle TK7800 Electronics. Computer engineering. Computer hardware. Photoelectronic devices
Zaidon, Nuradawiyah
Mohd Mansor, Ahmad Fairuzabadi
Wing, Cheung Mak
Ismail, Ahmad Faris
Nordin, Anis Nurashikin
Microfluidic concentration gradient for toxicity studies of lung carcinoma cells
description Cancer is a serious global health problem, which resulted in 8.2 million deaths in 2012 alone. Amongst different types of cancer, lung cancer is the most lethal and contributes 19.4% of cancer deaths. Better disease-free cancer survival rates have been reported when surgery is followed by systemic chemotherapy. Efficient treatment can be achieved through personalized chemotherapy dosage whereby optimum treatment is given to kill the cancer the side effects are minimized. Here, we present a microfluidic concentration gradient device for toxicity studies on lung cancer cell lines (A549). Automated drug dilution is achieved by simply tuning the flow rate and geometries of the microfluidics network. Sets of tree-like-concentration-generators were designed to achieve constant flow rate at each outlet by optimizing the channel lengths. Serpentine structures were placed in the middle in the middle and at each outlet channel to the design to improve mixing along the channel. The lengths of middle and outlet channels are varied from 1.5 mm to 12 mm to obtain sufficient mixing of two fluid flows. Theoretically, correlations between hydraulic flow and electrical circuit equations analogy were applied to ease the microfluidic design process. Later, 3D (dimensional) simulations using computational fluid dynamic (CFD)-based simulator, i.e. Ansys FLUENT were performed by implementing species transport method prior to fabrication. The simulation process helps to demonstrate the effect of varying channel length on the velocity magnitude and the concentration of the microfluidic structure. In addition, the simulation results allows us predict the fluid flow velocity that showed constant velocity magnitude at each outlet. Wider range of dilution can be achieved, when a higher number of outlets are added in a microfluidic design. Polydimethylsiloxane (PDMS) microchannels were fabricated on glass slide widths of 200 μm and depths of 35 μm using soft-lithography technique [1]. The 3-outlet serpentine structure produced the best match between simulation and measurement results. The concentration profiles produce inside the channel is determined by the splitting ratio of the fluids at each branched and also depends on the number of the inlet and outlet in the tree-like network. The gradient generator will be attached to an array of cell culture chambers with sensors that were previously developed for toxicity studies of lung cancer (A549) cell lines is shown in the Fig. 2. Cells cultured in the sensor will begin to attach and spread on the surface of the electrodes, restricting current flows from the electrodes to the surrounding media. In a confluent (all surface covered with cells) cell layer, current must travel through the intercellular space of the cell-cell and also the tight gap of the cell-electrode pairs to reach surrounding media. The more adhered the cells are with each other and with the electrode, the lesser the amount of current that could travel out, thus increasing the overall impedance of the system. This leads to a good way of studying cell-cell and cell-electrode adhesion characteristics by using impedance measurement [2] ; [3]. When sensors are treated with Taxol, the cell index (CI) values of the cancer cells exhibit inconsistent trend with several peaks during the measurement (over 96 hours) as shown in Fig.1. This is due to the nature of cells that are mixed combinations of drug-sensitive cells and drug resistance cells. This work provides a promising solution for automated drug dilution in parallel toxicity studies. The use of microfluidics allows highly parallel, maximum testing with minimal reagents to obtain the optimum dosage.
format Article
author Zaidon, Nuradawiyah
Mohd Mansor, Ahmad Fairuzabadi
Wing, Cheung Mak
Ismail, Ahmad Faris
Nordin, Anis Nurashikin
author_facet Zaidon, Nuradawiyah
Mohd Mansor, Ahmad Fairuzabadi
Wing, Cheung Mak
Ismail, Ahmad Faris
Nordin, Anis Nurashikin
author_sort Zaidon, Nuradawiyah
title Microfluidic concentration gradient for toxicity studies of lung carcinoma cells
title_short Microfluidic concentration gradient for toxicity studies of lung carcinoma cells
title_full Microfluidic concentration gradient for toxicity studies of lung carcinoma cells
title_fullStr Microfluidic concentration gradient for toxicity studies of lung carcinoma cells
title_full_unstemmed Microfluidic concentration gradient for toxicity studies of lung carcinoma cells
title_sort microfluidic concentration gradient for toxicity studies of lung carcinoma cells
publisher Elsevier
publishDate 2017
url http://irep.iium.edu.my/57788/1/1-s2.0-S2212017317300683-main.pdf
http://irep.iium.edu.my/57788/
http://www.sciencedirect.com/science/article/pii/S2212017317300683
_version_ 1643615220351893504
spelling my.iium.irep.577882018-01-11T06:02:21Z http://irep.iium.edu.my/57788/ Microfluidic concentration gradient for toxicity studies of lung carcinoma cells Zaidon, Nuradawiyah Mohd Mansor, Ahmad Fairuzabadi Wing, Cheung Mak Ismail, Ahmad Faris Nordin, Anis Nurashikin TK7800 Electronics. Computer engineering. Computer hardware. Photoelectronic devices Cancer is a serious global health problem, which resulted in 8.2 million deaths in 2012 alone. Amongst different types of cancer, lung cancer is the most lethal and contributes 19.4% of cancer deaths. Better disease-free cancer survival rates have been reported when surgery is followed by systemic chemotherapy. Efficient treatment can be achieved through personalized chemotherapy dosage whereby optimum treatment is given to kill the cancer the side effects are minimized. Here, we present a microfluidic concentration gradient device for toxicity studies on lung cancer cell lines (A549). Automated drug dilution is achieved by simply tuning the flow rate and geometries of the microfluidics network. Sets of tree-like-concentration-generators were designed to achieve constant flow rate at each outlet by optimizing the channel lengths. Serpentine structures were placed in the middle in the middle and at each outlet channel to the design to improve mixing along the channel. The lengths of middle and outlet channels are varied from 1.5 mm to 12 mm to obtain sufficient mixing of two fluid flows. Theoretically, correlations between hydraulic flow and electrical circuit equations analogy were applied to ease the microfluidic design process. Later, 3D (dimensional) simulations using computational fluid dynamic (CFD)-based simulator, i.e. Ansys FLUENT were performed by implementing species transport method prior to fabrication. The simulation process helps to demonstrate the effect of varying channel length on the velocity magnitude and the concentration of the microfluidic structure. In addition, the simulation results allows us predict the fluid flow velocity that showed constant velocity magnitude at each outlet. Wider range of dilution can be achieved, when a higher number of outlets are added in a microfluidic design. Polydimethylsiloxane (PDMS) microchannels were fabricated on glass slide widths of 200 μm and depths of 35 μm using soft-lithography technique [1]. The 3-outlet serpentine structure produced the best match between simulation and measurement results. The concentration profiles produce inside the channel is determined by the splitting ratio of the fluids at each branched and also depends on the number of the inlet and outlet in the tree-like network. The gradient generator will be attached to an array of cell culture chambers with sensors that were previously developed for toxicity studies of lung cancer (A549) cell lines is shown in the Fig. 2. Cells cultured in the sensor will begin to attach and spread on the surface of the electrodes, restricting current flows from the electrodes to the surrounding media. In a confluent (all surface covered with cells) cell layer, current must travel through the intercellular space of the cell-cell and also the tight gap of the cell-electrode pairs to reach surrounding media. The more adhered the cells are with each other and with the electrode, the lesser the amount of current that could travel out, thus increasing the overall impedance of the system. This leads to a good way of studying cell-cell and cell-electrode adhesion characteristics by using impedance measurement [2] ; [3]. When sensors are treated with Taxol, the cell index (CI) values of the cancer cells exhibit inconsistent trend with several peaks during the measurement (over 96 hours) as shown in Fig.1. This is due to the nature of cells that are mixed combinations of drug-sensitive cells and drug resistance cells. This work provides a promising solution for automated drug dilution in parallel toxicity studies. The use of microfluidics allows highly parallel, maximum testing with minimal reagents to obtain the optimum dosage. Elsevier 2017 Article REM application/pdf en http://irep.iium.edu.my/57788/1/1-s2.0-S2212017317300683-main.pdf Zaidon, Nuradawiyah and Mohd Mansor, Ahmad Fairuzabadi and Wing, Cheung Mak and Ismail, Ahmad Faris and Nordin, Anis Nurashikin (2017) Microfluidic concentration gradient for toxicity studies of lung carcinoma cells. Procedia Technology, 27. pp. 153-154. ISSN 2212-0173 http://www.sciencedirect.com/science/article/pii/S2212017317300683 10.1016/j.protcy.2017.04.067