Concentration gradient focusing and separation in a silica nanofluidic channel with a non-uniform electroosmotic flow

Single nanopores have attracted much scientific interest due to their versatile applications. The majority of experiments have been performed with nanopores being in contact with the same electrolyte on both sides of the membrane, while solution gradients across semi-permeable membranes are omnipresent in natural systems. In this manuscript, we studied ionic and fluidic movement through thin nanopores under viscosity gradients both experimentally and using simulations. Ionic current rectification was observed under these conditions, due to solutions with different conductivities filled across the pore under different bias es caused by electroosmotic flow. We found that a pore filled with high viscosity solutions exhibited current increase with applied voltage in a steeper slope beyond a threshold voltage, which abnormally reduced the current rectification ratio. Through simulations, we found reversed electroosmotic flow that filled the pore with aqueous solutions of lower viscosities was responsible for this behavior. The reversed electroosmotic flow could be explained by slower depletion of coions than counterions along the pore. By increasing the surface charge density of pore surfaces, current rectification ratio could reach the value of the viscosity gradient across thin nanopores.Our findings shed light on fundamental aspects to be considered when performing experiments with viscosity gradients across nanopores and nanofluidic channels.

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“…In Figure 6d, the velocity distribution of EOF in radial direction was similar to that found before under concentration gradients. 14…”

Section: Resultsmentioning

confidence: 99%

Abnormal Ionic-Current Rectification Caused by Reversed Electroosmotic Flow under Viscosity Gradients across Thin Nanopores

2018

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“…In a separate study, Startsev et al also demonstrated the potential for a DNA hybridization assay using this CGF device . Hsu et al also followed up with the initial experimental work by optimizing the nanochannel dimensions and developing a more complete understanding of the EOF profile .…”

Section: Counterflow Gradient Techniquesmentioning

confidence: 99%

Counterflow gradient electrophoresis for focusing and elution

Courtney

Ren

2019

Electrophoresis

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Counterflow gradient electrofocusing uses the bulk flow of a liquid solution to counterbalance the electrophoretic migration of an analyte. When either the bulk velocity or the electrophoretic velocity of the analyte is made to vary across the length of the channel, there exists a unique zero‐velocity point for the analyte. This focusing method enables simultaneous separation and concentration of different analytes. The high resolution and sensitivity achieved are similar to that of isoelectric focusing, which separates analytes based on their isoelectric points, but the key difference is that analytes will instead focus based on their electrophoretic mobility. Dynamically changing the applied voltage or the counterflow rate over time will shift the zero‐velocity point, and therefore allows the focused analytes to pass through a fixed detection point, or elute from the separation channel. Throughout the review, a number of different counterflow gradient techniques will be discussed, along with their recent advancements and potential applications.

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“…New approaches of microfluidic cell and particle trapping become increasingly important since lab‐on‐chip is emerging as an important territory for the development of new experimental procedures for cell‐based assays. Not only hydrodynamic effects have been exploited for retaining particles , but some special treatment such as isotachophoresis , temperature gradient , isoelectric , concentration gradient , dielectrophoresis , optical , magnetic or acoustic field that depends on field or field gradient induced force acting on particles has been utilized to enable cell trapping conditions as well. However, the new approach of microfluidic particle trapping, which generates relatively high throughput at the price of a low energy consumption in a simple chip structure that facilitates its integration with other functional microdevices is still a common target as pursued by the microfluidic community.…”

Section: Introductionmentioning

confidence: 99%

Enhanced particle trapping performance of induced charge electroosmosis

et al. 2016

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By increasing the number of floating electrodes or enlarging the width of single floating electrode, this work provides effective ways to strongly improve the particle trapping performance of induced charge electroosmosis (ICEO). Particle trapping with double or triple separate narrow floating electrodes increases the effective actuating range of ICEO flow and therefore enhance the optimum trapping ability to be 1.63 or 2.34 times of that with single narrow electrode (width of L=200μm), and the ideal trapping frequency is independent of the electrode number due to the mutual independence of electrochemical ion relaxation over each electrode. Furthermore, using a single wide floating electrode with the effective width equal to three separate narrow floating electrodes (L=600μm) instead of a single narrow one slightly lowers the ideal trapping frequency due to an increase in the characteristic polarization length, but the trapping performance is only up to 1.59 times of that with original single narrow electrode, implying that vertical channel confinement effect may severely suppresses the effective actuating range of ICEO flow and renders the trapping performance not as expected. Trapping experiments over wide floating electrode with different channel height were carried out, showing that the trapping performance increases by correctly increasing the channel height.

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Concentration gradient focusing and separation in a silica nanofluidic channel with a non-uniform electroosmotic flow

Cited by 31 publications

References 38 publications

Abnormal Ionic-Current Rectification Caused by Reversed Electroosmotic Flow under Viscosity Gradients across Thin Nanopores

Abnormal Ionic-Current Rectification Caused by Reversed Electroosmotic Flow under Viscosity Gradients across Thin Nanopores

Counterflow gradient electrophoresis for focusing and elution

Enhanced particle trapping performance of induced charge electroosmosis

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