Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique

Microfluidics-based biochips play a vital role in single-cell research applications. Handling and positioning of single cells at the microscale level are an essential need for various applications, including genomics, proteomics, secretomics, and lysis-analysis. In this article, the pipette Petri di...

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Main Authors: Narayanamurthy, Vigneswaran, Lee, Tze Pin, Al’aina Yuhainis, Firus Khan, Fahmi, Samsuri, Khairudin, Mohamed, Hairul Aini, Hamzah, Madia Baizura, Baharom
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Language:English
English
Published: MDPI AG 2018
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Online Access:http://umpir.ump.edu.my/id/eprint/23381/1/Pipette%20petri%20dish%20single-cell%20trapping%20%28PP-SCT%29%20in%20microfluidic%20platforms.pdf
http://umpir.ump.edu.my/id/eprint/23381/7/Pipette%20Petri%20Dish%20Single-Cell%20Trapping.pdf
http://umpir.ump.edu.my/id/eprint/23381/
https://doi.org/10.3390/fluids3030051
https://doi.org/10.3390/fluids3030051
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spelling my.ump.umpir.233812019-01-02T01:45:07Z http://umpir.ump.edu.my/id/eprint/23381/ Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique Narayanamurthy, Vigneswaran Lee, Tze Pin Al’aina Yuhainis, Firus Khan Fahmi, Samsuri Khairudin, Mohamed Hairul Aini, Hamzah Madia Baizura, Baharom TK Electrical engineering. Electronics Nuclear engineering Microfluidics-based biochips play a vital role in single-cell research applications. Handling and positioning of single cells at the microscale level are an essential need for various applications, including genomics, proteomics, secretomics, and lysis-analysis. In this article, the pipette Petri dish single-cell trapping (PP-SCT) technique is demonstrated. PP-SCT is a simple and cost-effective technique with ease of implementation for single cell analysis applications. In this paper a wide operation at different fluid flow rates of the novel PP-SCT technique is demonstrated. The effects of the microfluidic channel shape (straight, branched, and serpent) on the efficiency of single-cell trapping are studied. This article exhibited passive microfluidic-based biochips capable of vertical cell trapping with the hexagonally-positioned array of microwells. Microwells were 35 μm in diameter, a size sufficient to allow the attachment of captured cells for short-term study. Single-cell capture (SCC) capabilities of the microfluidic-biochips were found to be improving from the straight channel, branched channel, and serpent channel, accordingly. Multiple cell capture (MCC) was on the order of decreasing from the straight channel, branch channel, and serpent channel. Among the three designs investigated, the serpent channel biochip offers high SCC percentage with reduced MCC and NC (no capture) percentage. SCC was around 52%, 42%, and 35% for the serpent, branched, and straight channel biochips, respectively, for the tilt angle, θ values were between 10–15°. Human lung cancer cells (A549) were used for characterization. Using the PP-SCT technique, flow rate variations can be precisely achieved with a flow velocity range of 0.25–4 m/s (fluid channel of 2 mm width and 100 µm height). The upper dish (UD) can be used for low flow rate applications and the lower dish (LD) for high flow rate applications. Passive single-cell analysis applications will be facilitated using this method. MDPI AG 2018 Article PeerReviewed pdf en http://umpir.ump.edu.my/id/eprint/23381/1/Pipette%20petri%20dish%20single-cell%20trapping%20%28PP-SCT%29%20in%20microfluidic%20platforms.pdf pdf en http://umpir.ump.edu.my/id/eprint/23381/7/Pipette%20Petri%20Dish%20Single-Cell%20Trapping.pdf Narayanamurthy, Vigneswaran and Lee, Tze Pin and Al’aina Yuhainis, Firus Khan and Fahmi, Samsuri and Khairudin, Mohamed and Hairul Aini, Hamzah and Madia Baizura, Baharom (2018) Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique. Fluids, 3 (3). pp. 1-16. ISSN 2311-5521 https://doi.org/10.3390/fluids3030051 https://doi.org/10.3390/fluids3030051
institution Universiti Malaysia Pahang
building UMP Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaysia Pahang
content_source UMP Institutional Repository
url_provider http://umpir.ump.edu.my/
language English
English
topic TK Electrical engineering. Electronics Nuclear engineering
spellingShingle TK Electrical engineering. Electronics Nuclear engineering
Narayanamurthy, Vigneswaran
Lee, Tze Pin
Al’aina Yuhainis, Firus Khan
Fahmi, Samsuri
Khairudin, Mohamed
Hairul Aini, Hamzah
Madia Baizura, Baharom
Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique
description Microfluidics-based biochips play a vital role in single-cell research applications. Handling and positioning of single cells at the microscale level are an essential need for various applications, including genomics, proteomics, secretomics, and lysis-analysis. In this article, the pipette Petri dish single-cell trapping (PP-SCT) technique is demonstrated. PP-SCT is a simple and cost-effective technique with ease of implementation for single cell analysis applications. In this paper a wide operation at different fluid flow rates of the novel PP-SCT technique is demonstrated. The effects of the microfluidic channel shape (straight, branched, and serpent) on the efficiency of single-cell trapping are studied. This article exhibited passive microfluidic-based biochips capable of vertical cell trapping with the hexagonally-positioned array of microwells. Microwells were 35 μm in diameter, a size sufficient to allow the attachment of captured cells for short-term study. Single-cell capture (SCC) capabilities of the microfluidic-biochips were found to be improving from the straight channel, branched channel, and serpent channel, accordingly. Multiple cell capture (MCC) was on the order of decreasing from the straight channel, branch channel, and serpent channel. Among the three designs investigated, the serpent channel biochip offers high SCC percentage with reduced MCC and NC (no capture) percentage. SCC was around 52%, 42%, and 35% for the serpent, branched, and straight channel biochips, respectively, for the tilt angle, θ values were between 10–15°. Human lung cancer cells (A549) were used for characterization. Using the PP-SCT technique, flow rate variations can be precisely achieved with a flow velocity range of 0.25–4 m/s (fluid channel of 2 mm width and 100 µm height). The upper dish (UD) can be used for low flow rate applications and the lower dish (LD) for high flow rate applications. Passive single-cell analysis applications will be facilitated using this method.
format Article
author Narayanamurthy, Vigneswaran
Lee, Tze Pin
Al’aina Yuhainis, Firus Khan
Fahmi, Samsuri
Khairudin, Mohamed
Hairul Aini, Hamzah
Madia Baizura, Baharom
author_facet Narayanamurthy, Vigneswaran
Lee, Tze Pin
Al’aina Yuhainis, Firus Khan
Fahmi, Samsuri
Khairudin, Mohamed
Hairul Aini, Hamzah
Madia Baizura, Baharom
author_sort Narayanamurthy, Vigneswaran
title Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique
title_short Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique
title_full Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique
title_fullStr Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique
title_full_unstemmed Pipette petri dish single-cell trapping (PP-SCT) in microfluidic platforms: A passive hydrodynamic technique
title_sort pipette petri dish single-cell trapping (pp-sct) in microfluidic platforms: a passive hydrodynamic technique
publisher MDPI AG
publishDate 2018
url http://umpir.ump.edu.my/id/eprint/23381/1/Pipette%20petri%20dish%20single-cell%20trapping%20%28PP-SCT%29%20in%20microfluidic%20platforms.pdf
http://umpir.ump.edu.my/id/eprint/23381/7/Pipette%20Petri%20Dish%20Single-Cell%20Trapping.pdf
http://umpir.ump.edu.my/id/eprint/23381/
https://doi.org/10.3390/fluids3030051
https://doi.org/10.3390/fluids3030051
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