On the use of correction factors for the mathematical modeling of insulator based dielectrophoretic devices

Hill, Nicole; Lapizco‐Encinas, Blanca H.

doi:10.1002/elps.201900177

Cited by 32 publications

(40 citation statements)

References 58 publications

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“…It is because the particle's disturbances to the electric field (and as well the flow field) were neglected in the model. Such a treatment has been proved effective in our earlier studies as well as in those from other research groups [55]. To calculate the Clausius-Mosotti factor, f CM , in Equation 3, we assumed that the electric conductivity of polystyrene particles is determined solely by the surface conduction, σ s = 1 nS, through σ p = 4σ s /d [56].…”

Section: Numerical Modelingmentioning

confidence: 99%

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Malekanfard

Beladi-Behbahani

et al. 2020

Micromachines

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Focusing particles into a tight stream is critical for many microfluidic particle-handling devices such as flow cytometers and particle sorters. This work presents a fundamental study of the passive focusing of polystyrene particles in ratchet microchannels via direct current dielectrophoresis (DC DEP). We demonstrate using both experiments and simulation that particles achieve better focusing in a symmetric ratchet microchannel than in an asymmetric one, regardless of the particle movement direction in the latter. The particle focusing ratio, which is defined as the microchannel width over the particle stream width, is found to increase with an increase in particle size or electric field in the symmetric ratchet microchannel. Moreover, it exhibits an almost linear correlation with the number of ratchets, which can be explained by a theoretical formula that is obtained from a scaling analysis. In addition, we have demonstrated a DC dielectrophoretic focusing of yeast cells in the symmetric ratchet microchannel with minimal impact on the cell viability.

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Section: Numerical Modelingmentioning

confidence: 99%

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Malekanfard

Beladi-Behbahani

et al. 2020

Micromachines

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“…Only a handful of reports in the field of microscale EK separations have considered the effects of EP (3) in detail: five recent developments by our group [7,8,23,25,36] and the recent work of Rouhi et al [37] and Tottori et al [33]. Until recently, correction factors [38] were commonly added to mathematical models to improve the accuracy of modeling predictions. Considering the effects of EP (3) , which are enhanced at the constriction regions between posts due to the higher local electric field magnitude, allows for the first proper design of EK injection schemes by employing mathematical modeling.…”

Section: Methodsmentioning

confidence: 99%

Fine-Tuning Electrokinetic Injections Considering Nonlinear Electrokinetic Effects in Insulator-Based Devices

et al. 2021

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The manner of sample injection is critical in microscale electrokinetic (EK) separations, as the resolution of a separation greatly depends on sample quality and how the sample is introduced into the system. There is a significant wealth of knowledge on the development of EK injection methodologies that range from simple and straightforward approaches to sophisticated schemes. The present study focused on the development of optimized EK sample injection schemes for direct current insulator-based EK (DC-iEK) systems. These are microchannels that contain arrays of insulating structures; the presence of these structures creates a nonuniform electric field distribution when a potential is applied, resulting in enhanced nonlinear EK effects. Recently, it was reported that the nonlinear EK effect of electrophoresis of the second kind plays a major role in particle migration in DC-iEK systems. This study presents a methodology for designing EK sample injection schemes that consider the nonlinear EK effects exerted on the particles being injected. Mathematical modeling with COMSOL Multiphysics was employed to identify proper voltages to be used during the EK injection process. Then, a T-microchannel with insulating posts was employed to experimentally perform EK injection and separate a sample containing two types of similar polystyrene particles. The quality of the EK injections was assessed by comparing the resolution (Rs) and number of plates (N) of the experimental particle separations. The findings of this study establish the importance of considering nonlinear EK effects when planning for successful EK injection schemes.

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“…This is an aspect of protein DEP within the mesoscale between [CM] macroscopic and [CM] molecular , where κ or N dip , respectively, may or may not equal unity in either Equation ( 21) or (50), respectively. As reviewed by Hill and Lapizco-Encinas [104], significant efforts have been made to mathematically model iDEP-based microfluidic devices and to identify empirical correction factors that can be added to align model predictions with experimental observations. These correction factors are intended to take account of electrothermally induced fluid flow, Joule heating, particle-particle interactions and temperature gradients, for example.…”

Section: Idepmentioning

confidence: 99%

“…These correction factors are intended to take account of electrothermally induced fluid flow, Joule heating, particle-particle interactions and temperature gradients, for example. For micronsized particles (e.g., bacteria, blood cells, polystyrene beads and yeast cells) most correction factors are found to be small (0.3 to ~15), whilst particles of diameter ~1 µm attract larger correction factors-in some cases as large as 500~600, depending on the geometry and layout of the insulating posts, hurdles or restrictions [104].…”

Section: Idepmentioning

confidence: 99%

Protein Dielectrophoresis: A Tale of Two Clausius-Mossottis—Or Something Else?

Pethig

2022

Micromachines

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Standard DEP theory, based on the Clausius–Mossotti (CM) factor derived from solving the boundary-value problem of macroscopic electrostatics, fails to describe the dielectrophoresis (DEP) data obtained for 22 different globular proteins over the past three decades. The calculated DEP force appears far too small to overcome the dispersive forces associated with Brownian motion. An empirical theory, employing the equivalent of a molecular version of the macroscopic CM-factor, predicts a protein’s DEP response from the magnitude of the dielectric β-dispersion produced by its relaxing permanent dipole moment. A new theory, supported by molecular dynamics simulations, replaces the macroscopic boundary-value problem with calculation of the cross-correlation between the protein and water dipoles of its hydration shell. The empirical and formal theory predicts a positive DEP response for protein molecules up to MHz frequencies, a result consistently reported by electrode-based (eDEP) experiments. However, insulator-based (iDEP) experiments have reported negative DEP responses. This could result from crystallization or aggregation of the proteins (for which standard DEP theory predicts negative DEP) or the dominating influences of electrothermal and other electrokinetic (some non-linear) forces now being considered in iDEP theory.

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On the use of correction factors for the mathematical modeling of insulator based dielectrophoretic devices

Cited by 32 publications

References 58 publications

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Passive Dielectrophoretic Focusing of Particles and Cells in Ratchet Microchannels

Fine-Tuning Electrokinetic Injections Considering Nonlinear Electrokinetic Effects in Insulator-Based Devices

Protein Dielectrophoresis: A Tale of Two Clausius-Mossottis—Or Something Else?

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