Particle manipulations in non-Newtonian microfluidics: A review

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Microfluidic devices have been extensively used to achieve precise transport and placement of a variety of particles for numerous applications. A range of force fields have thus far been demonstrated to control the motion of particles in microchannels. Among them, electric field‐driven particle manipulation may be the most popular and versatile technique because of its general applicability and adaptability as well as the ease of operation and integration into lab‐on‐a‐chip systems. This article is aimed to review the recent advances in direct current (DC) (and as well DC‐biased alternating current) electrokinetic manipulation of particles for microfluidic applications. The electric voltages are applied through electrodes that are positioned into the distant channel‐end reservoirs for a concurrent transport of the suspending fluid and manipulation of the suspended particles. The focus of this review is upon the cross‐stream nonlinear electrokinetic motions of particles in the linear electroosmotic flow of fluids, which enable the diverse control of particle transport in microchannels via the wall‐induced electrical lift and/or the insulating structure‐induced dielectrophoretic force.

Section: Discussionmentioning

confidence: 99%

Recent advances in direct current electrokinetic manipulation of particles for microfluidic applications

Xuan

2019

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“…In a conventional flow cytometer, the sample sorting is achieved by deflecting the charged droplets under an electric field. For the microfluidic flow cytometry, many different microchip sorting systems have been described . Generally, it can be divided into active and passive methods.…”

Section: Flow Control In Microfluidic Flow Cytometrymentioning

confidence: 99%

New advances in microfluidic flow cytometry

Gong

Fan

et al. 2018

In recent years, researchers are paying the increasing attention to the development of portable microfluidic diagnostic devices including microfluidic flow cytometry for the point‐of‐care testing. Microfluidic flow cytometry, where microfluidics and flow cytometry work together to realize novel functionalities on the microchip, provides a powerful tool for measuring the multiple characteristics of biological samples. The development of a portable, low‐cost, and compact flow cytometer can benefit the health care in underserved areas such as Africa or Asia. In this article, we review recent advancements of microfluidics including sample pumping, focusing and sorting, novel detection approaches, and data analysis in the field of flow cytometry. The challenge of microfluidic flow cytometry is also examined briefly.

“…It has been suggested in recent studies to be viewed as a combination of two opposing force components: one is the center‐directed elastic lift component,

F_{e L \to c}

, due to fluid elasticity, and the other is the wall‐directed elastic lift component,

F_{e L \to w}

, due to fluid elasticity and shear thinning. The total elastic lift,

{boldF}_{e L} = {boldF}_{e L \to c} + {boldF}_{e L \to w}

, is expressed in the following scale ,

{boldF}_{e L} \sim d^{3} λ \nabla {\overset{γ}{true}}^{2},

where d is the (equivalent) spherical cell diameter, λ is the fluid relaxation time, and

\overset{γ}{true}

is the fluid shear rate. It increases with the Weissenberg number,

W i

W i = λ \dot{γ} = λ \frac{2 U}{w} = \frac{2 λ Q}{w^{2} h}

where U is the average fluid velocity, w is the channel width, Q is the volumetric flow rate, and h is the channel height.…”

Section: Theorymentioning

confidence: 99%

Continuous sheath‐free separation of drug‐treated human fungal pathogen Cryptococcus neoformans by morphology in biocompatible polymer solutions

Zielinski

Kozubowski

et al. 2018

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Cryptococcal meningitis caused by Cryptococcus neoformans is the leading cause of fungal central nervous system infections. Current antifungal treatments for cryptococcal infections are inadequate partly due to the occurrence of drug resistance. Recent studies indicate that the treatment of the azole drug fluconazole changes the morphology of C. neoformans to form enlarged "multimeras" that consist of three or more connected cells/buds. To analyze if these multimeric cells are a prerequisite for C. neoformans to acquire drug resistance, a tool capable of separating them from normal cells is critical. We extend our recently demonstrated sheath-free elasto-inertial particle separation technique to fractionate drug-treated C. neoformans cells by morphology in biocompatible polymer solutions. The separation performance is evaluated for both multimeric and normal cells in terms of three dimensionless metrics: efficiency, purity, and enrichment ratio. The effects of flow rate, polymer concentration, and microchannel height on cell separation are studied.