Dielectrophoretic Manipulation and Separation of Microparticles Using Microarray Dot Electrodes

Yafouz, Bashar; Kadri, Nahrizul Adib; Ibrahim, Fatimah

doi:10.3390/s140406356

Cited by 54 publications

(41 citation statements)

References 49 publications

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“…iDEP has been used for manipulation and separation of inert microparticles to a great extent . Manipulation of bioparticles such as bacteria , algae , mammalian cells , sperm cells , and DNA has also been reported.…”

Section: Introductionmentioning

confidence: 99%

Dielectrophoretic behavior of PEGylated RNase A inside a microchannel with diamond‐shaped insulating posts

et al. 2015

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Ribonuclease A (RNase A) has proven potential as a therapeutic agent, especially in its PEGylated form. Grafting of PEG molecules to this protein yields mono-PEGylated (mono-PEG) and di-PEGylated (di-PEG) RNase A conjugates, and the unreacted protein. Mono-PEG RNase A is of great interest. The use of electrokinetic forces in microdevices represents a novel alternative to chromatographic methods to separate this specie. This work describes the dielectrophoretic behavior of the main protein products of the RNase A PEGylation inside a microchannel with insulators under direct current electric fields. This approach represents the first step in route to design micro-bioprocesses to separate PEGylated RNase A from unreacted native protein. The three proteins exhibited different dielectrophoretic behaviors. All of them experienced a marked streaming pattern at 3000 V consistent with positive dielectrophoresis. Native protein was not captured at any of the conditions tested, while mono-PEG RNase A and di-PEG RNase A were captured presumably due to positive dielectrophoresis at 4000 and 2500 V, respectively. Concentration of mono-PEG RNase A with a maximal enrichment efficiency of ≈9.6 times the feed concentration was achieved in few seconds. These findings open the possibility of designing novel devices for rapid separation, concentration, and recovery of PEGylated RNase A in a one-step operation.

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Section: Introductionmentioning

confidence: 99%

Dielectrophoretic behavior of PEGylated RNase A inside a microchannel with diamond‐shaped insulating posts

et al. 2015

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“…Figure illustrates the design and operation of the dielectrophoresis device used in the current work, which was introduced and validated in . The microarray dot electrodes were fabricated by using standard photolithography process.…”

Section: Electrode Arrangement In Microfluidic Device For Dielectrophmentioning

confidence: 99%

“…(A) Dielectrophoresis device layers and a close‐up view of the 4 × 4 microarray dot electrode, with cells distributed homogenously in the microchannel provided by the microfluidic gasket. (B) Cells distributed homogenously over the dot area before the electrical signal is applied (1), cells experiencing the positive dielectrophoresis effect and thus being attracted to the dot electrode edge (2), and cells collected at the dot center under the effect of negative dielectrophoresis (3) .…”

Section: Electrode Arrangement In Microfluidic Device For Dielectrophmentioning

confidence: 99%

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Microfluidic device embedding electrodes for dielectrophoretic manipulation of cells‐A review

et al. 2018

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Microfluidic device embedding electrodes realizes cell manipulation with the help of dielectrophoresis. Cell manipulation is an important technology for cell sorting and cell population purification. Till now, the theory of dielectrophoresis has been greatly developed. Microfluidic devices with various arrangements of electrodes have been reported from the beginning of the single non‐uniform electric field to the later multiple physical fields. This paper reviews the research status of microfluidic device embedding electrodes for cell manipulation based on dielectrophoresis. Firstly, the working principle of dielectrophoresis is explained. Next, cell manipulation approaches based on dielectrophoresis are introduced. Then, different types of electrode arrangements in the microfluidic device for cell manipulation are discussed, including planar, multilayered and microarray dot electrodes. Finally, the future development trend of the dielectrophoresis with the help of microfluidic devices is prospected. With the rapid development of microfluidic technology, in the near future, high precision, high throughput, high efficiency, multifunctional, portable, economical and practical microfluidic dielectrophoresis will be widely used in the fields of biology, medicine, agriculture and so on.

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“…We characterized the differences in particle trapping when using waveforms with a given frequency and either equivalent peak‐to‐peak voltages (V pp ), equivalent wave energy (E x ) or equivalent RMS voltage (V RMS ). The frequency range of 5–50 kHz was used for this work due to previous work showing pDEP for 1.1 μm polystyrene beads . The Clausius‐Mossotti factor for these experiments decreased by 0.05 across this frequency range.…”

mentioning

confidence: 99%

Assessing the importance of the root mean square (RMS) value of different waveforms to determine the strength of a dielectrophoresis trapping force

et al. 2017

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Dielectrophoretic Manipulation and Separation of Microparticles Using Microarray Dot Electrodes

Cited by 54 publications

References 49 publications

Dielectrophoretic behavior of PEGylated RNase A inside a microchannel with diamond‐shaped insulating posts

Dielectrophoretic behavior of PEGylated RNase A inside a microchannel with diamond‐shaped insulating posts

Microfluidic device embedding electrodes for dielectrophoretic manipulation of cells‐A review

Assessing the importance of the root mean square (RMS) value of different waveforms to determine the strength of a dielectrophoresis trapping force

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