2016
DOI: 10.1021/acs.analchem.6b02104
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Continuous On-Chip Cell Separation Based on Conductivity-Induced Dielectrophoresis with 3D Self-Assembled Ionic Liquid Electrodes

Abstract: Dielectrophoresis (DEP) has been widely explored to separate cells for various applications. However, existing DEP devices are limited by the high cost associated with the use of noble metal electrodes, the need of high-voltage electric field, and/or discontinuous separation (particularly for devices without metal electrodes). We developed a DEP device with liquid electrodes, which can be used to continuously separate different types of cells or particles based on positive DEP. The device is made of polydimeth… Show more

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Cited by 47 publications
(55 citation statements)
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“…However, a number of methodologies have recently emerged 199 , including those using conducting polymers 200 , silver-PDMS 201 , liquid metals 202 , screen printing 203 and vapor deposition, constructed by techniques of micromolding 204 , semiconductor fabrication 205,206,207,208,209 , and low-cost bonding methods on hybrid platforms 210,203 . The reduced dead volumes of such 3D electrode platforms have been applied to enhance the spatial extents of the field non-uniformity 211,212 to enable high throughput separations 213,214 , cytometry 215,216 , sample enrichment for biomolecular determination 217,218 , sample transport by traveling-wave dielectrophoresis 219,220,221 , and dielectric characterization of cells by electro-rotation 222,223,224 .…”
Section: Challenges and Emerging Needsmentioning
confidence: 99%
“…However, a number of methodologies have recently emerged 199 , including those using conducting polymers 200 , silver-PDMS 201 , liquid metals 202 , screen printing 203 and vapor deposition, constructed by techniques of micromolding 204 , semiconductor fabrication 205,206,207,208,209 , and low-cost bonding methods on hybrid platforms 210,203 . The reduced dead volumes of such 3D electrode platforms have been applied to enhance the spatial extents of the field non-uniformity 211,212 to enable high throughput separations 213,214 , cytometry 215,216 , sample enrichment for biomolecular determination 217,218 , sample transport by traveling-wave dielectrophoresis 219,220,221 , and dielectric characterization of cells by electro-rotation 222,223,224 .…”
Section: Challenges and Emerging Needsmentioning
confidence: 99%
“…(C) PC‐3 cells separated by conductivity‐induced dielectrophoresis. Adapted with permission from , © 2016 American Chemical Society. (D) Illustration of living CD45 neg /EpCAM neg cells isolation device using oDEP.…”
Section: Cell Viability Assessmentmentioning
confidence: 99%
“…In 2016, He's group developed a novel DEP device with liquid electrodes for the separation of living/dead PC‐3 human prostate cancer cells. Ionic liquid (140 mS/m), which was immiscible with the suspending medium (10% w/v sucrose, 0.3% w/v glucose, and 0.8% v/v PBS, 14 mS/m), was used as the electrode.…”
Section: Cell Viability Assessmentmentioning
confidence: 99%
“…Because most biological cells have dielectric characteristics in an external electric field, cells in suspension can be controlled by DEP force or torque. [70][71][72] Cells can be stimulated to travel to the region with a strong electric field by a positive DEP force in the non-uniform electric field, or conversely, to the area with a weak electric field by a negative DEP force.…”
Section: Dielectrophoresismentioning
confidence: 99%