Continuous separation and manipulation of particles and cells using dielectrophoresis

Cell manipulation and separation are critical in biomedical diagnosis. Typical techniques such as flow cytometry require costly and bulky instruments. Microfluidics holds promise in minimization and integration of such biomedical routine processes onto a portable and affordable chip. It also offers...

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Main Author: Lewpiriyawong Nuttawut
Other Authors: Yang Chun, Charles
Format: Theses and Dissertations
Language:English
Published: 2011
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Online Access:https://hdl.handle.net/10356/46440
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-464402023-03-11T17:50:36Z Continuous separation and manipulation of particles and cells using dielectrophoresis Lewpiriyawong Nuttawut Yang Chun, Charles School of Mechanical and Aerospace Engineering DRNTU::Engineering::Mechanical engineering::Fluid mechanics Cell manipulation and separation are critical in biomedical diagnosis. Typical techniques such as flow cytometry require costly and bulky instruments. Microfluidics holds promise in minimization and integration of such biomedical routine processes onto a portable and affordable chip. It also offers faster analysis with less sample/reagent volume. Field-Flow Fractionation (FFF) employing dielectrophoresis (DEP) in microfluidics is an emerging technique for continuous manipulation and separation of cells. Although microfluidic DEP-FFF techniques can overcome some FFF-associated problems such as sample band broadening and slow separation, most microfluidic DEP-FFF devices utilize AC electric field generated by metal electrodes fabricated on silicon or glass substrates. This study focuses on implementation of DEP-FFF techniques into polymer microfluidic devices for continuous separation, sorting, and concentration of particles and cells. The modified PDMS-based H-filter platform with multi-insulating blocks is developed for sorting and continuous separation of particles. The use of a single-channel DC power supply greatly simplifies the device operation. The multi-insulating blocks not only can enhance DC-DEP force but also focus particles in a small region, thereby facilitating particle separation. In order to establish critical guidelines for optimal device configurations, the effects of the number and geometrical structures of insulating blocks on the threshold voltages are investigated. The effectiveness of the proposed technique using combined AC and DC field is experimentally and numerically evident by reducing the threshold voltage in separation. Moreover, a novel microfluidic technique utilizing a combined AC and DC electric field is also developed for particle and cell concentration under a continuous-flow condition. Findings obtained from both the experiments and simulation show a significant reduction in the threshold voltage by 85.9%. Experimental results suggest that higher buffer concentration, larger particle size and higher ratio of AC-to-DC electric fields improve DEP concentration performance. In addition, a new PDMS-based microfluidic device with 3D conducting PDMS composites as sidewall electrodes is developed for characterization and separation of particles and cells by AC-DEP. The developed fabrication technique greatly facilitates (i) the integration of the conducting PDMS composite electrodes with PDMS microchannels, and (ii) device assembly by using only oxygen plasma treatment. With these features, the device can be operated at relatively high flow rates without liquid leakage. Unlike conventional 2D planar electrodes, 3D conducting PDMS electrodes can produce 3D electric field that distributes uniformly throughout the entire channel height and varies along the channel lateral direction, thereby giving rise to stronger DEP forces and also allowing for lateral manipulation and observation of particles and cells. The high efficiency (>97%) proves the device capability to effectively separate various samples including submicron particles, micron particles, live and dead yeast cells and bacterial cells under continuous-flow conditions. DOCTOR OF PHILOSOPHY (MAE) 2011-12-06T03:03:19Z 2011-12-06T03:03:19Z 2011 2011 Thesis Lewpiriyawong, N. (2011). Continuous separation and manipulation of particles and cells using dielectrophoresis. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/46440 10.32657/10356/46440 en 218 p. application/pdf text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html text/html
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Mechanical engineering::Fluid mechanics
spellingShingle DRNTU::Engineering::Mechanical engineering::Fluid mechanics
Lewpiriyawong Nuttawut
Continuous separation and manipulation of particles and cells using dielectrophoresis
description Cell manipulation and separation are critical in biomedical diagnosis. Typical techniques such as flow cytometry require costly and bulky instruments. Microfluidics holds promise in minimization and integration of such biomedical routine processes onto a portable and affordable chip. It also offers faster analysis with less sample/reagent volume. Field-Flow Fractionation (FFF) employing dielectrophoresis (DEP) in microfluidics is an emerging technique for continuous manipulation and separation of cells. Although microfluidic DEP-FFF techniques can overcome some FFF-associated problems such as sample band broadening and slow separation, most microfluidic DEP-FFF devices utilize AC electric field generated by metal electrodes fabricated on silicon or glass substrates. This study focuses on implementation of DEP-FFF techniques into polymer microfluidic devices for continuous separation, sorting, and concentration of particles and cells. The modified PDMS-based H-filter platform with multi-insulating blocks is developed for sorting and continuous separation of particles. The use of a single-channel DC power supply greatly simplifies the device operation. The multi-insulating blocks not only can enhance DC-DEP force but also focus particles in a small region, thereby facilitating particle separation. In order to establish critical guidelines for optimal device configurations, the effects of the number and geometrical structures of insulating blocks on the threshold voltages are investigated. The effectiveness of the proposed technique using combined AC and DC field is experimentally and numerically evident by reducing the threshold voltage in separation. Moreover, a novel microfluidic technique utilizing a combined AC and DC electric field is also developed for particle and cell concentration under a continuous-flow condition. Findings obtained from both the experiments and simulation show a significant reduction in the threshold voltage by 85.9%. Experimental results suggest that higher buffer concentration, larger particle size and higher ratio of AC-to-DC electric fields improve DEP concentration performance. In addition, a new PDMS-based microfluidic device with 3D conducting PDMS composites as sidewall electrodes is developed for characterization and separation of particles and cells by AC-DEP. The developed fabrication technique greatly facilitates (i) the integration of the conducting PDMS composite electrodes with PDMS microchannels, and (ii) device assembly by using only oxygen plasma treatment. With these features, the device can be operated at relatively high flow rates without liquid leakage. Unlike conventional 2D planar electrodes, 3D conducting PDMS electrodes can produce 3D electric field that distributes uniformly throughout the entire channel height and varies along the channel lateral direction, thereby giving rise to stronger DEP forces and also allowing for lateral manipulation and observation of particles and cells. The high efficiency (>97%) proves the device capability to effectively separate various samples including submicron particles, micron particles, live and dead yeast cells and bacterial cells under continuous-flow conditions.
author2 Yang Chun, Charles
author_facet Yang Chun, Charles
Lewpiriyawong Nuttawut
format Theses and Dissertations
author Lewpiriyawong Nuttawut
author_sort Lewpiriyawong Nuttawut
title Continuous separation and manipulation of particles and cells using dielectrophoresis
title_short Continuous separation and manipulation of particles and cells using dielectrophoresis
title_full Continuous separation and manipulation of particles and cells using dielectrophoresis
title_fullStr Continuous separation and manipulation of particles and cells using dielectrophoresis
title_full_unstemmed Continuous separation and manipulation of particles and cells using dielectrophoresis
title_sort continuous separation and manipulation of particles and cells using dielectrophoresis
publishDate 2011
url https://hdl.handle.net/10356/46440
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