Parametric study on the geometrical parameters of a lab-on-a-chip platform with tilted planar electrodes for continuous dielectrophoretic manipulation of microparticles

Dalili, Arash; Taatizadeh, Erfan; Tahmooressi, Hamed; Tasnim, Nishat; Rellstab-Sánchez, Pamela Inés; Shaunessy, Matthew; Najjaran, Homayoun; Hoorfar, Mina

doi:10.1038/s41598-020-68699-4

Cited by 22 publications

(19 citation statements)

References 53 publications

(52 reference statements)

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“…( 9)) and the vibration velocities of the substrate (u x and u y are substrate displacement components in eqn. (5) and eqn. ( 6)) is regarded as the interface tangential velocities u a0 and v a0 which can be expressed as 39 ,…”

Section: Limiting Velocity Methodsmentioning

confidence: 99%

“…Manipulation of microparticles is of utmost importance in a wide array of biomedical, biochemical, and biophysical applications [1][2][3] . Since the emergence of lab-on-a-chip (LoC) technologies, especially in the past two decades, different manipulation strategies, including electrokinetic, hydrodynamic, optical, magnetophoretic, and acoustophoretic based method have been developed [4][5][6][7] . Each method has its portfolio of strengths and weaknesses, which makes them suitable for a particular application.…”

Section: Introductionmentioning

confidence: 99%

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3D Numerical Simulation of Acoustophoretic Motioninduced by Boundary-driven Acoustic Streaming Instanding Surface Acoustic wave Microfluidics

Namnabat

Zand

Houshfar

2021

Preprint

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Standing surface acoustic waves (SSAWs) have been widely utilized in microfluidic devices to manipulate various cells and micro/nano-objects. Despite widespread application, a time-/cost-efficient versatile 3D model that predicts the particle behavior in such platforms is still lacking. Herein, a fully-coupled 3D numerical simulation of boundary-driven acoustic streaming in the acoustofluidic devices utilizing SSAWs has been conducted based on the limiting velocity finite element method. Through this efficient computational method, the underlying physical interplay from the electromechanical fields of the piezoelectric substrate to different acoustofluidic effects (acoustic radiation force and streaming-induced drag force), fluid-solid interactions, the 3D influence of novel on-chip configuration like tilted-angle SSAW (taSSAW) based devices, required boundary conditions, meshing technique, and demanding computational cost, are discussed. As an experimental validation, a taSSAW platform fabricated on YX 128 LiNbO3 substrate for separating polystyrene beads is simulated, which demonstrates acceptable agreement with reported experimental observations. Subsequently, as an application of the presented 3D model, a novel sheathless taSSAW cell/particle separator is conceptualized and designed. The presented 3D fully-coupled model, due to the more time-/cost-efficient performance than precedented 3D models, the capability to model complex on-chip configurations, and overcome shortcomings and limitations of 2D simulations could be considered as a powerful tool in further the designing and optimizing SSAW microfluidics.

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Section: Limiting Velocity Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

3D Numerical Simulation of Acoustophoretic Motioninduced by Boundary-driven Acoustic Streaming Instanding Surface Acoustic wave Microfluidics

Namnabat

Zand

Houshfar

2021

Preprint

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“…Microfiltration [4], inertia‐based [5], pinched flow fractionation [6], and deterministic lateral displacement [7] are among the passive methods. Dielectrophoretic [8], acoustophoretic [9], magnetic [10], and optic forces [11] are the most popular active methods used for sorting and separation. The mechanisms, advantages, and disadvantages of each one of these methods are reviewed in detail in the literature [2,12].…”

Section: Introductionmentioning

confidence: 99%

“…Several studies have investigated the effect of different geometrical as well as operational parameters on the DEP‐induced displacement of the particles. In our previous study [8], we investigated the effect of the geometry of the electrodes, applied voltage, volumetric throughput, particle size, as well as the height, width, and length of the microchannel on the displacement of the particles. COMSOL Multiphysics simulation results showed that by decreasing the electrode gap and increasing the electrode width to a critical value, which depends on the channel height, the DEP force enhances significantly.…”

Section: Introductionmentioning

confidence: 99%

Sheath‐assisted versus sheathless dielectrophoretic particle separation

Dalili

Hoorfar

2021

Electrophoresis

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Lab‐on‐chip devices are widely being used for binary and ternary cell/particle separation applications. Among the lab‐on‐chip methods, dielectrophoresis (DEP) is a cost‐effective and label‐free method, with great capabilities for size‐based separation of cells and particles, which is mostly performed in sheath‐assisted forms. However, the elimination of the sheath flows offers advantages such as ease of operation and higher sample throughput. In this work, we present a comparison of sheath‐assisted and sheathless DEP separation of three sizes of microparticles using tilted electrodes. The sheath‐assisted design was capable of separating the 5, 10, and 15 μm particles with a separation efficiency as high as 98.0% for 15 μm particles. By adding a DEP focusing region, a sheathless DEP separator was proposed, which offered higher throughputs (up to 10 times) at the cost of lowering the separation efficiency (a reduction up to 10.3% for 15 μm) compared to the sheath‐assisted design. To enhance the separation efficiency, a combination of the DEP focusing accompanied by weak sheath flows from both sides was proposed. This design achieved the highest sample separation yield in the outlets (as high as 98.7% for 15 μm) with a sample throughput of more than 4.2 μL/min. This study provides insights into the choice of an appropriate platform for any application in which the yield, purity, throughput, and portability must be considered.

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“…The levitation of cells by n-DEP will decrease the separation effect. Recently, the electrode geometries of slanted electrodes were investigated by the simulation of the induced electric field for the effective and high throughput separation of particles [ 24 ].…”

Section: Introductionmentioning

confidence: 99%

Microfluidic Separation of Blood Cells Based on the Negative Dielectrophoresis Operated by Three Dimensional Microband Electrodes

et al. 2020

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A microfluidic device is presented for the continuous separation of red blood cells (RBCs) and white blood cells (WBCs) in a label-free manner based on negative dielectrophoresis (n-DEP). An alteration of the electric field, generated by pairs of slanted electrodes (separators) that is fabricated by covering parts of single slanted electrodes with an insulating layer is used to separate cells by their sizes. The repulsive force of n-DEP formed by slanted electrodes prepared on both the top and bottom substrates led to the deflection of the cell flow in lateral directions. The presence of gaps covered with an insulating layer for the electric field on the electrodes allows the passing of RBCs through gaps, while relatively large WBCs (cultured cultured human acute monocytic leukemia cell line (THP-1 cells)) flowed along the slanted separator without passing through the gaps and arrived at an edge in the channel. The passage efficiency for RBCs through the gaps and the arrival efficiency for THP-1 cells to the upper edge in the channel were estimated and found to be 91% and 93%, respectively.

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Parametric study on the geometrical parameters of a lab-on-a-chip platform with tilted planar electrodes for continuous dielectrophoretic manipulation of microparticles

Cited by 22 publications

References 53 publications

3D Numerical Simulation of Acoustophoretic Motioninduced by Boundary-driven Acoustic Streaming Instanding Surface Acoustic wave Microfluidics

3D Numerical Simulation of Acoustophoretic Motioninduced by Boundary-driven Acoustic Streaming Instanding Surface Acoustic wave Microfluidics

Sheath‐assisted versus sheathless dielectrophoretic particle separation

Microfluidic Separation of Blood Cells Based on the Negative Dielectrophoresis Operated by Three Dimensional Microband Electrodes

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