Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads
This paper presents the use of DC-biased AC electric field for enhancing cell trapping throughput in an insulator-based dielectrophoretic (iDEP) fluidic device with densely packed silica beads. Cell suspension is carried through the iDEP device by a pressure-driven flow. Under an applied DC-biased A...
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sg-ntu-dr.10356-1422032020-06-17T05:30:13Z Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads Lewpiriyawong, Nuttawut Xu, Guolin Yang, Chun School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Cell Trapping DC‐biased AC Electric Field This paper presents the use of DC-biased AC electric field for enhancing cell trapping throughput in an insulator-based dielectrophoretic (iDEP) fluidic device with densely packed silica beads. Cell suspension is carried through the iDEP device by a pressure-driven flow. Under an applied DC-biased AC electric field, DEP trapping force is produced as a result of non-uniform electric field induced by the gap of electrically insulating silica beads packed between two mesh electrodes that allow both fluid and cells to pass through. While the AC component is mainly to control the magnitude of DEP trapping force, the DC component generates local electroosmotic (EO) flow in the cavity between the beads and the EO flow can be set to move along or against the main pressure-driven flow. Our experimental and simulation results show that desirable trapping is achieved when the EO flow direction is along (not against) the main flow direction. Using our proposed DC-biased AC field, the device can enhance the trapping throughput (in terms of the flowrate of cell suspension) up to five times while yielding almost the same cell capture rates as compared to the pure AC field case. Additionally, the device was demonstrated to selectively trap dead yeast cells from a mixture of flowing live and dead yeast cells. MOE (Min. of Education, S’pore) 2020-06-17T05:30:13Z 2020-06-17T05:30:13Z 2018 Journal Article Lewpiriyawong, N., Xu, G., & Yang, C. (2018). Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads. Electrophoresis, 39(5-6), 878-886. doi:10.1002/elps.201700395 0173-0835 https://hdl.handle.net/10356/142203 10.1002/elps.201700395 29288585 2-s2.0-85040782580 5-6 39 878 886 en Electrophoresis © 2017 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. |
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Engineering::Mechanical engineering Cell Trapping DC‐biased AC Electric Field |
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Engineering::Mechanical engineering Cell Trapping DC‐biased AC Electric Field Lewpiriyawong, Nuttawut Xu, Guolin Yang, Chun Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| description |
This paper presents the use of DC-biased AC electric field for enhancing cell trapping throughput in an insulator-based dielectrophoretic (iDEP) fluidic device with densely packed silica beads. Cell suspension is carried through the iDEP device by a pressure-driven flow. Under an applied DC-biased AC electric field, DEP trapping force is produced as a result of non-uniform electric field induced by the gap of electrically insulating silica beads packed between two mesh electrodes that allow both fluid and cells to pass through. While the AC component is mainly to control the magnitude of DEP trapping force, the DC component generates local electroosmotic (EO) flow in the cavity between the beads and the EO flow can be set to move along or against the main pressure-driven flow. Our experimental and simulation results show that desirable trapping is achieved when the EO flow direction is along (not against) the main flow direction. Using our proposed DC-biased AC field, the device can enhance the trapping throughput (in terms of the flowrate of cell suspension) up to five times while yielding almost the same cell capture rates as compared to the pure AC field case. Additionally, the device was demonstrated to selectively trap dead yeast cells from a mixture of flowing live and dead yeast cells. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Lewpiriyawong, Nuttawut Xu, Guolin Yang, Chun |
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Article |
| author |
Lewpiriyawong, Nuttawut Xu, Guolin Yang, Chun |
| author_sort |
Lewpiriyawong, Nuttawut |
| title |
Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| title_short |
Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| title_full |
Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| title_fullStr |
Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| title_full_unstemmed |
Enhanced cell trapping throughput using DC-biased AC electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| title_sort |
enhanced cell trapping throughput using dc-biased ac electric field in a dielectrophoresis-based fluidic device with densely packed silica beads |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/142203 |
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