New Generation Dielectrophoretic-Based Microfluidic Device for Multi-Type Cell Separation

Sharbati, Pouya; Sadaghiani, Abdolali Khalili; Koşar, Ali

doi:10.3390/bios13040418

Cited by 8 publications

(1 citation statement)

References 55 publications

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“…The algae cells, Haematococcus Pluvialis and Bracteacoccus Engadinensis were separated at 100V voltage amplitude and 8 KHz frequency. P. Sharbati developed a dielectrophoretic-based microfluidic device to separate multiple cell types [24]. The bioparticles were separated using cylindrical electrodes in the first section and sidewall electrodes in the second section.…”

Section: Introductionmentioning

confidence: 99%

A comprehensive analysis of enhanced microfluidic device for detection of Pathogenic Bacteria and CTCs in the bloodstream

Brahma,

Kumar,

Narzary

2024

Preprint

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In the current research scenario, microfluidics has gained immense attention in the field of medical diagnostics. However, a decisive platform for segregating multiple bioparticles like pathogenic bacteria, and CTCs from blood cells needs to be instigated. This paper proposes a microfluidic chip for the segregation of multiple bioparticles like pathogenic bacteria and CTCs from blood cells. Utilizing the Navier- Stokes equation for configuring the fluid flow in the microchannel, the study leverages the dielectrophoresis technique for manipulating target bacterial and cancer cells with a diameter of 1 µm and 16–30 µm respectively. The main channel of the microfluidic device has uniquely designed electrodes to generate the non-uniform electric field for manipulating the particles through different outlets. The blood, bacteria, and cancer cells are introduced through the inlet at the velocity of 100 µl/s and the buffer solution with a flow velocity of 700 µl/s. The analysis showed that at the electrode voltage of 14 Vp-p, the target bioparticles are separated efficiently. The chip is designed using the COMSOL Multiphysics tool, an advanced and promising platform for early detection of bloodstream bacterial infection and CTCs with perfect separation efficiency and purity.

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Section: Introductionmentioning

confidence: 99%

A comprehensive analysis of enhanced microfluidic device for detection of Pathogenic Bacteria and CTCs in the bloodstream

Brahma,

Kumar,

Narzary

2024

Preprint

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Recent developments toward microfluidic point-of-care diagnostic sensors for viral infections

Zarean Mousaabadi,

Talebi Vandishi,

Kermani

et al. 2023

TrAC Trends in Analytical Chemistry

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Separating live and dead yeast cells in a serpentine microchannel using Dielectrophoresis

Puri,

Sharma,

Garg

2024

E3S Web Conf.

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Separation techniques and particle manipulation has always been a matter of curiosity to research groups worldwide for numerous biomedical applications like cell concentration, separation, patterning, and trapping. The present work describes the fabrication and testing for constant cell separation using Dielectrophoresis phenomenon. The cells with different electric properties separate continuously at different location as they flow across the channel. Known mixture of non viable and viable yeast cells is selectively trapped using negative Dielectrophoresis. We achieved the cell trapping efficiency of 98%. A serpentine structure in the cell separation device appears to be a design choice that addresses the need for continuous separation and improved efficiency by minimizing dead volume.

show abstract

New Generation Dielectrophoretic-Based Microfluidic Device for Multi-Type Cell Separation

Cited by 8 publications

References 55 publications

A comprehensive analysis of enhanced microfluidic device for detection of Pathogenic Bacteria and CTCs in the bloodstream

A comprehensive analysis of enhanced microfluidic device for detection of Pathogenic Bacteria and CTCs in the bloodstream

Recent developments toward microfluidic point-of-care diagnostic sensors for viral infections

Separating live and dead yeast cells in a serpentine microchannel using Dielectrophoresis

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