2019
DOI: 10.1021/acs.analchem.9b01104
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Continuous Cell Characterization and Separation by Microfluidic Alternating Current Dielectrophoresis

Abstract: A novel alternating current (ac)-dielectrophoretic (DEP) microfluidic chip for continuous cell characterization and separation is presented in this paper. To generate DEP forces, two electrode-pads are embedded in a set of asymmetric orifices on the opposite sidewalls to produce the nonuniform electric fields. In the vicinity of a small orifice, the cells experience the strongest nonuniform gradient and are drawn toward it by the positive DEP forces, while the cells experiencing a negative DEP force are repell… Show more

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Cited by 72 publications
(41 citation statements)
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“…A similar reservoir‐based DEP device was also proposed recently (Fig. 6C) . There was an asymmetric orifice placed on one side of the main channel.…”
Section: Cell Viability Assessmentmentioning
confidence: 96%
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“…A similar reservoir‐based DEP device was also proposed recently (Fig. 6C) . There was an asymmetric orifice placed on one side of the main channel.…”
Section: Cell Viability Assessmentmentioning
confidence: 96%
“…(C) Cell separation by small orifice‐based DEP. Adapted with permission from , © 2019 American Chemical Society. (D) Continuous field‐flow cell separation with 3D electrodes.…”
Section: Cell Viability Assessmentmentioning
confidence: 99%
“…Dielectrophoresis (DEP) is a technique that utilises an inhomogeneous electric field to move particles according to their polarisability [ 185 , 186 ]. It can be an effective, high-throughput method for manipulating different cell populations through differences in their polarisability [ 187 , 188 ]. It is a non-invasive technique, and may be used without detriment to the cells under examination [ 189 ].…”
Section: Electrical Biosensorsmentioning
confidence: 99%
“…This means that DEP can be used with an alternating current (AC). This is important for the application of DEP to cells, as the capacitive effects of the cell membrane are negligible at higher frequencies [ 140 ], enabling separation of cell populations based not on the external media, but on the size of the cell and conductivity of the cell cytoplasm [ 188 ]. This has been utilised by Modarres et al in a “frequency hopping” DEP to capture cells at one frequency and selectively release the unwanted cells at another [ 211 ], as shown in Figure 17 .…”
Section: Electrical Biosensorsmentioning
confidence: 99%
“…Rather than limited by proximity to a planar interdigitated electrode array on a single channel surface, placing potential and ground on opposite sides of the channel allows the DEP force to be applied further in to the fluid domain. Extending the application, electrodes on either sidewall have been developed to achieve lateral separation of a number of analytes [14,52,53]. By changing the distance between electrodes the field magnitude can be spatially mapped, and cell separation can be tuned even further, improving sensitivity and allowing for either batch or continuous separations.…”
Section: D Electrode Systemsmentioning
confidence: 99%