Electroporation of cells in microfluidic devices: a review

Fox, Martijn B.; Esveld, D.C.; Valero, Ana; Lüttge, Regina; Mastwijk, H.C.; Bartels, PV; Berg, Albert van den; Boom, R. G. H.

doi:10.1007/s00216-006-0327-3

Cited by 234 publications

(179 citation statements)

References 82 publications

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Section: Electroporation On Cell or Cells: Electrode Manipulation To mentioning

confidence: 99%

“…With the integration of several steps, continuous electroporation using flow-through microchips or other microfluidic devices were reported (Lin et al 2002;Fox et al 2006). At present these electroporation devices were roughly divided into three categories: analyzing cellular properties or intracellular content, transfecting cells and inactivating cells (Fox et al 2006). Chip methods help to manipulate cells in a single manner under different parameters at the same time, which makes comparison of different settings on the same chip possible; nevertheless most of the chips so far have focused on studies of the electroporation process, and the in situ detection and live screening might add further value to these devices.…”

Section: Electroporation On Cell or Cells: Electrode Manipulation To mentioning

confidence: 99%

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Electroporation: an arsenal of application

Yuan

2007

Cytotechnology

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Electroporation is a way to induce nanometersized membrane pore for exogenous substances delivery into cytoplasm using an artificial electric field. Now it was widely used for molecules transfer especially in molecular experiments and genetic aspects. In recent years, modern electroporation on the embryo was developed, whose most important point is that it adopts low energy and rectangular pulse that could obtain high transfection efficiency and low damage to the embryo. This paper reviewed on the pool of application: from lab works to human clinical treatments.

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Section: Electroporation On Cell or Cells: Electrode Manipulation To mentioning

confidence: 99%

Section: Electroporation On Cell or Cells: Electrode Manipulation To mentioning

confidence: 99%

Electroporation: an arsenal of application

Yuan

2007

Cytotechnology

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“…14-20 Electrical lysis of cells has been accomplished on microchip devices typically using a total voltage across the electrodes from 6 V to 1.4 kV depending on the intra-electrode distance. 13,14,16,[21][22][23][24] When the electric potential of the electrodes surpasses 2.06 V, electrolysis of water occurs, resulting in the formation of gas at the electrode. 25 This gas formation can rapidly obstruct a microchannel leading to electrophoretic failure in both microfluidic and capillary-based electrophoresis.…”

Section: Introductionmentioning

confidence: 99%

Fast-lysis cell traps for chemical cytometry

et al. 2008

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Electrically addressable cell traps were integrated with capillary electrophoresis for the analysis of the contents of single adherent cells. Electrodes composed of indium tin oxide were patterned on a glass surface followed by formation of topographical cell traps using 1002F photoresist. Single cells trapped in the holes could be lysed in less than 66 ms by applying a brief electric field (10 ms) across the electrode beneath the cell and the ground electrode placed in the aqueous media above the cell traps. The gas formed during cell lysis remained localized within the cavity formed by the 1002F photoresist. The retention of the gas in the cell trap enabled the cell traps to be coupled to an overlying capillary without blockage of the capillary. Single cells cultured in the traps were loaded with fluorescein and Oregon Green and then electrically lysed. By simultaneous application of an electric field to the capillary, the cell's contents were loaded into the capillary and electrophoretically separated. Orgeon Green and fluorescein from a single cell were fully resolved in less than two minutes. The use of a single patterned electrode beneath the 1002F cell trap yielded a simple easily fabricated design that was robust when immersed in aqueous solutions. Moreover, the design can easily be scaled up to create arrays of adherent cells for serial analyses using a single capillary or for parallel analysis by mating to an array of capillaries. Enhancing the rate of analysis of single adherent cells would enable a greater understanding of cellular physiology.

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“…When subjected to an electric field, dielectric particles such as cells, experience a range of electrokinetic forces, pressures and torques 50 . An external electric field can induce formation of pores in cell membranes, move cells by DEP and fuse membranes 51 .…”

Section: Cell Pairing By Dielectrophoresismentioning

confidence: 99%

“…With positive DEP the cells align towards the region of the highest electric field, see figure 3. At higher frequencies (~1-100 MHz), the field will bridge the membrane and the CM factor will compare the permittivity of the cytoplasm and the media, resulting in negative DEP at higher solution conductivities and positive DEP at low solution conductivities 50,[58][59][60] . Finally, the application of high frequencies (>1 GHz) will result in negative DEP, likely due to cytoplasmic proteins that impart a net permittivity lower than the surrounding medium 64 .…”

Section: Electrofusion Of Cells On Chip (Thesis Ewm Kemna)mentioning

confidence: 99%

Droplet microfluidic platform for cell electrofusion

Schoeman¹

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Electroporation of cells in microfluidic devices: a review

Cited by 234 publications

References 82 publications

Electroporation: an arsenal of application

Electroporation: an arsenal of application

Fast-lysis cell traps for chemical cytometry

Droplet microfluidic platform for cell electrofusion

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