Negative Dielectrophoretic Capture and Repulsion of Single Cells at a Bipolar Electrode: The Impact of Faradaic Ion Enrichment and Depletion

Anand, Robbyn K.; Johnson, Eleanor S.; Chiu, Daniel T.

doi:10.1021/ja5102689

Cited by 53 publications

(54 citation statements)

References 34 publications

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“…[20][21][22][23] Furthermore, the highly localized nature of DEP behavior, due to its dependence on rE 2 , limits its spatial extent. 13,24 Herein, by initiating ICP at lateral perm-selective constrictions of large surface charge non-uniformity, we create conductivity differences across the nanoslit length to enhance the spatial extent for biomarker depletion. As a result, the localized field (E) is enhanced due to ion depletion at the constriction tips, whereas ion accumulation along the constriction sidewalls increases the field gradient (rE), thereby dramatically enhancing the magnitude and spatial extent of nDEP, due to its rE 2 dependence.…”

Section: Introductionmentioning

confidence: 99%

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

et al. 2016

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Selective and rapid enrichment of biomolecules is of great interest for biomarker discovery, protein crystallization, and in biosensing for speeding assay kinetics and reducing signal interferences. The current state of the art is based on DC electrokinetics, wherein localized ion depletion at the microchannel to nanochannel interface is used to enhance electric fields, and the resulting biomarker electromigration is balanced against electro-osmosis in the microchannel to cause high degrees of biomarker enrichment. However, biomarker enrichment is not selective, and the levels fall off within physiological media of high conductivity, due to a reduction in ion concentration polarization and electro-osmosis effects. Herein, we present a methodology for coupling AC electrokinetics with ion concentration polarization effects in nanoslits under DC fields, for enabling ultrafast biomarker enrichment in physiological media. Using AC fields at the critical frequency necessary for negative dielectrophoresis of the biomarker of interest, along with a critical offset DC field to create proximal ion accumulation and depletion regions along the perm-selective region inside a nanoslit, we enhance the localized field and field gradient to enable biomarker enrichment over a wide spatial extent along the nanoslit length. While enrichment under DC electrokinetics relies solely on ion depletion to enhance fields, this AC electrokinetic mechanism utilizes ion depletion as well as ion accumulation regions to enhance the field and its gradient. Hence, biomarker enrichment continues to be substantial in spite of the steady drop in nanostructure perm-selectivity within physiological media. Published by AIP Publishing. [http://dx

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Section: Introductionmentioning

confidence: 99%

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

et al. 2016

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“…Compared to the single-cell isolation and analysis devices with multi-layer architecture, the SD-DEP chip described here does not require complex device fabrication and operations such as valves and mixing. The steps of cell analysis using SD-DEP chip are depicted in Scheme 1: A) prime the device with Pluronic F-127 solution to effectively inhibit cell adhesion on PDMS surface, B) fill the trapping channels and chambers with specific buffers and reagents (here, low electrical conductivity (LEC) DEP buffer [18] (8.0% sucrose, 0.3% dextrose, and 0.1% BSA in 1.0 mM Tris (pH 8.0, conductivity σ = 6.2 mS/m)) was applied for cell trapping), C) apply optimized trapping voltage and flow in the cell sample and trap cells at chamber openings, D) flush the excess cells with LEC buffer, turn off the trapping voltage and inject fresh loop mediated isothermal amplification (LAMP) reaction buffer to dispense the trapped cells into the chambers, E) fill the channel with the immiscible phase to isolate cells in the compartments, F) lyse cells and initiate single-cell LAMP reaction. The strength of this experimental design is three-fold.…”

mentioning

confidence: 99%

“…Second, the active cell sorting method developed here relies on external DEP force without the use of cell labeling, which provides greater specificity and control of the force employed for cell capture than passive sorting mechanisms or spontaneous digitization alone. [18, 20] This label free cell sorting method has important advantages for conducting high fidelity single cell molecular analyses, such as minimized antibody related costs, applicability to cells lacking biomarkers, and maintaining integrity of endogenous biomarker expression. Finally, features such as the dimensions of the chamber opening and control over DEP force provide means to limit capture in each chamber to one cell.…”

mentioning

confidence: 99%

“…[17] Herein, we present the development of aself-digitization dielectrophoretic (SD-DEP) chip that enables rapid, convenient, and highly efficient capture and on-demand release of single suspended cells into separated chambers for downstream nucleic acid analysis using inexpensive and simple components.C ompared to the single-cell isolation and analysis devices with multi-layer architecture,t he SD-DEP chip described herein does not require complex device fabrication and operations such as valves and mixing. The steps of cell analysis using SD-DEP chip are depicted in Scheme 1: A) Thed evice is primed with Pluronic F-127 solution to effectively inhibit cell adhesion on PDMS surface, B) the trapping channels and chambers are filled with specific buffers and reagents (here,low electrical conductivity (LEC) DEP buffer [18] (8.0 %sucrose,0.3 %dextrose,and 0.1 %BSA in 1.0 mm Tris (pH 8.0, conductivity s = 6.2 mS m À1 )) was applied for cell trapping), C) optimized trapping voltage and flow are applied in the cell sample and cells trapped at chamber openings,D )the excess cells are flushed with LEC buffer, the trapping voltage turned off,a nd fresh loop mediated isothermal amplification (LAMP) reaction buffer injected to dispense the trapped cells into the chambers, E) the channel is filled with the immiscible phase to isolate cells in the compartments,a nd F) cells are lysed and single-cell LAMP reaction initiates.The strength of this experimental design is three-fold. First, the introduction of an immiscible phase takes advantage of an existing robust technology self-digitization (SD) chip that we have developed.…”

mentioning

confidence: 99%

“…[19] This technology employs inherent fluidic phenomena to spontaneously divide an aqueous solution into nanoliter-scale waterin-oil plugs in an array of microfluidic chambers.Each waterin-oil emulsion plug formed on the SD-DEP chip can function as an independent chemical reactor, handling an extremely small volume of liquid containing cells and reagents for following molecular analysis of single cell lysates.Second, the active cell sorting method developed herein relies on external DEP force without the use of cell labeling,w hich provides greater specificity and control of the force employed for cell capture than passive sorting mechanisms or spontaneous digitization alone. [18,20] This label-free cell-sorting method has important advantages for conducting high-fidelity single-cell molecular analyses,such as minimized antibody related costs, applicability to cells lacking biomarkers,a nd maintaining integrity of endogenous biomarker expression. Finally,f eatures such as the dimensions of the chamber opening and control over DEP force provide means to limit capture in each chamber to one cell.…”

mentioning

confidence: 99%

See 2 more Smart Citations

A Self‐Digitization Dielectrophoretic (SD‐DEP) Chip for High‐Efficiency Single‐Cell Capture, On‐Demand Compartmentalization, and Downstream Nucleic Acid Analysis

Qin

Schneider

et al. 2018

Angew Chem Int Ed

Self Cite

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The design and fabrication of a self-digitization dielectrophoretic (SD-DEP) chip with simple components for single-cell manipulation and downstream nucleic acid analysis is presented. The device employed the traditional DEP and insulator DEP to create the local electric field that is tailored to approximately the size of single cells, enabling highly efficient single-cell capture. The multistep procedures of cell manipulation, compartmentalization, lysis, and analysis were performed in the integrated microdevice, consuming minimal reagents, minimizing contamination, decreasing lysate dilution, and increasing assay sensitivity. The platform developed here could be a promising and powerful tool in single-cell research for precise medicine.

show abstract

A Self‐Digitization Dielectrophoretic (SD‐DEP) Chip for High‐Efficiency Single‐Cell Capture, On‐Demand Compartmentalization, and Downstream Nucleic Acid Analysis

Qin

Schneider

et al. 2018

Angewandte Chemie

Self Cite

View full text Add to dashboard Cite

The design and fabrication of a self‐digitization dielectrophoretic (SD‐DEP) chip with simple components for single‐cell manipulation and downstream nucleic acid analysis is presented. The device employed the traditional DEP and insulator DEP to create the local electric field that is tailored to approximately the size of single cells, enabling highly efficient single‐cell capture. The multistep procedures of cell manipulation, compartmentalization, lysis, and analysis were performed in the integrated microdevice, consuming minimal reagents, minimizing contamination, decreasing lysate dilution, and increasing assay sensitivity. The platform developed here could be a promising and powerful tool in single‐cell research for precise medicine.

show abstract

Negative Dielectrophoretic Capture and Repulsion of Single Cells at a Bipolar Electrode: The Impact of Faradaic Ion Enrichment and Depletion

Cited by 53 publications

References 34 publications

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

A Self‐Digitization Dielectrophoretic (SD‐DEP) Chip for High‐Efficiency Single‐Cell Capture, On‐Demand Compartmentalization, and Downstream Nucleic Acid Analysis

A Self‐Digitization Dielectrophoretic (SD‐DEP) Chip for High‐Efficiency Single‐Cell Capture, On‐Demand Compartmentalization, and Downstream Nucleic Acid Analysis

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