Dielectrophoretic manipulation of particle mixtures employing asymmetric insulating posts

Saucedo-Espinosa, Mario A.; LaLonde, Alexandra; Gencoglu, Aytug; Romero-Creel, Maria F.; Dolas, Jay R.; Lapizco‐Encinas, Blanca H.

doi:10.1002/elps.201500195

Cited by 40 publications

(50 citation statements)

References 39 publications

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“…(H) Enrichment of yeast cells in a microdevice with asymmetric posts, the two images illustrate the outlet of the post array where yeast cells (labelled green) accumulated for their subsequent release and elution. Reprinted from , copyright (2015) John Wiley and Sons. (I) Illustration of an EπDEP device depicting the embedded passivated electrodes (600 μm wide) and two columns of cylindrical insulating posts within.…”

Section: Advances On Devices For Trapping Idepmentioning

confidence: 99%

“…A sinusoidal AC signal with a positive DC bias was utilized to separate a sample containing 1 and 2 μm polystyrene particles and yeast cells in 120 s. The particles were enriched and separated in “dielectropherogram” scheme. In a more recent contribution, this group reported the use of asymmetric posts to invert particle elution order when carrying out a particle separation process . By carefully designing a custom DC‐biased AC signal, this group was able to enrich and selectively elute first the larger particles present in a mixture.…”

Section: Advances On Devices For Trapping Idepmentioning

confidence: 99%

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On the recent developments of insulator‐based dielectrophoresis: A review

2018

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Insulator-based dielectrophoresis (iDEP), also known as electrodeless DEP, has become a well-known dielectrophoretic technique, no longer viewed as a new methodology. Significant advances on iDEP have been reported during the last 15 years. This review article aims to summarize some of the most important findings on iDEP organized by the type of dielectrophoretic mode: streaming and trapping iDEP. The former is primarily used for particle sorting, while the latter has great capability for particle enrichment. The characteristics of a wide array of devices are discussed for each type of dielectrophoretic mode in order to present an overview of the distinct designs and applications developed with iDEP. A short section on Joule heating effects and electrothermal flow is also included to highlight some of the challenges in the utilization of iDEP systems. The significant progress on iDEP illustrates its potential for a large number of applications, ranging from bioanalysis to clinical and biomedical assessments. The present article discusses the work on iDEP by numerous research groups around the world, with the aim of proving the reader with an overview of the state-of-the-art in iDEP microfluidic systems.

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Section: Advances On Devices For Trapping Idepmentioning

confidence: 99%

Section: Advances On Devices For Trapping Idepmentioning

confidence: 99%

On the recent developments of insulator‐based dielectrophoresis: A review

2018

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“…iDEP is a particle confining technique based on the movement of matter in inhomogeneous electric fields that employs insulating structures embedded in a microchannel to produce electric field gradients [36,37,38,39]. The inhomogeneous electric field required for iDEP platforms is induced when the cross-sectional area of the microchannel is “pinched” by the presence of electrically insulating structures between external electrodes [38].…”

Section: Dep Backgroundmentioning

confidence: 99%

“…While in [38], the iDEP showed that particles’ size and the shape of microelectrode have significant effects on the magnitude, location, and shape of the DEP trapping regions. On the other hand, in [39] the researchers were able to segregate certain bio-particles by using asymmetric shaped insulating posts coupled with low-frequency electric potentials. Moreover, the electrodes in [40] were fabricated onto quartz substrates using photolithography technique and were used for the direct mapping of the suspended particles’ spatial concentrations.…”

Section: Dep Backgroundmentioning

confidence: 99%

Dielectrophoresis for Biomedical Sciences Applications: A Review

Rahman

Ibrahim

Yafouz

2017

Sensors

170

155

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Dielectrophoresis (DEP) is a label-free, accurate, fast, low-cost diagnostic technique that uses the principles of polarization and the motion of bioparticles in applied electric fields. This technique has been proven to be beneficial in various fields, including environmental research, polymer research, biosensors, microfluidics, medicine and diagnostics. Biomedical science research is one of the major research areas that could potentially benefit from DEP technology for diverse applications. Nevertheless, many medical science research investigations have yet to benefit from the possibilities offered by DEP. This paper critically reviews the fundamentals, recent progress, current challenges, future directions and potential applications of research investigations in the medical sciences utilizing DEP technique. This review will also act as a guide and reference for medical researchers and scientists to explore and utilize the DEP technique in their research fields.

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“…Unlike traditional DEP, cDEP does not require the electrodes to be in direct contact with the cell suspension, but rather uses fluidic electrodes containing an electrolyte solution separated from the main cell‐flow channel by a thin membrane. Separating the electrodes from the fluid in the device eliminates electrolysis and improves cell viability by preventing cell‐to‐electrode contact . Analogous to insulator‐based DEP (iDEP), insulating posts within the channel create gradients in the electric field that drive the DEP force .…”

Section: Introductionmentioning

confidence: 99%

A feasibility study for enrichment of highly aggressive cancer subpopulations by their biophysical properties via dielectrophoresis enhanced with synergistic fluid flow

et al. 2017

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A common problem with cancer treatment is the development of treatment resistance and tumor recurrence that result from treatments that kill most tumor cells yet leave behind aggressive cells to repopulate. Presented here is a microfluidic device that can be used to isolate tumor subpopulations to optimize treatment selection. Dielectrophoresis (DEP) is a phenomenon where particles are polarized by an electric field and move along the electric field gradient. Different cell subpopulations have different DEP responses depending on their bioelectrical phenotype, which, we hypothesize, correlate with aggressiveness. We have designed a microfluidic device in which a region containing posts locally distorts channel of the electric field created by an AC voltage across a microfluidic channel and which forces cells toward the posts through DEP. This force is balanced with a simultaneous drag force from fluid motion that pulls cells away from the posts. We have shown that by adjusting the drag force, cells with aggressive phenotypes are influenced more by the DEP force and trap on posts while others flow through the chip unaffected. Utilizing single-cell trapping on cell-sized posts by a drag-DEP force balance, we show that separation of very similar cell subpopulations may be achieved, a result that was previously impossible with DEP alone. Separated subpopulations maintain high viability downstream, and remain in a native state, without fluorescent labeling. These cells can then be cultured to help select a therapy that kills aggressive subpopulations equally or better than the bulk of the tumor, mitigating resistance and recurrence.

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Dielectrophoretic manipulation of particle mixtures employing asymmetric insulating posts

Cited by 40 publications

References 39 publications

On the recent developments of insulator‐based dielectrophoresis: A review

On the recent developments of insulator‐based dielectrophoresis: A review

Dielectrophoresis for Biomedical Sciences Applications: A Review

A feasibility study for enrichment of highly aggressive cancer subpopulations by their biophysical properties via dielectrophoresis enhanced with synergistic fluid flow

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