Capillarity ion concentration polarization for spontaneous biomolecular preconcentration mechanism

Lab-on-a-chip has been used widely in rapid, high-throughput and low-consumption analysis of samples in biochemistry. The ion concentration polarization (ICP) produced by ion-selective transport of nanochannels provides a novel solution for problems in ultra-low concentration sample detection, systems biology and desalination. This paper reviews the applications of ion transport based on the principle of ICP in micro-nanofluidic systems. First, the fundamental governing equations of ICP are described. Then, the applications of nano-electrokinetic ion enrichment and ion current rectification (ICR) are introduced. Nano-electrokinetic ion enrichment is used mainly in the fields of molecular enrichment, ultra-low concentration sample detection and seawater desalination. ICR is applied mainly to the sensitive detection of analytical substances such as proteins, nucleic acids and small molecules. The application of ion transport based on ICP principle is summarized and the possible directions worthy of further research are proposed.

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“…It affects local charge concentration and material transport. With the ICP effect, ion transport can be selectively controlled …”

Section: Introductionmentioning

confidence: 99%

A review: applications of ion transport in micro‐nanofluidic systems based on ion concentration polarization

Han

Chen

2019

J of Chemical Tech & Biotech

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“…Our previous work presented the spontaneous preconcentration (or selective preconcentration) method in microfluidic chip with leveraging convective flow through microchannel over diffusiophoresis induced by imbibition and ion exchange of ion exchange medium, respectively [13][14][15][16][17][18]. Especially, we had demonstrated that the velocity of the convective flow by the imbibition of the medium deviated from original Darcy's law using non-uniformly patterned ion exchange medium, but this work has the limitation of time-consuming and complex process [13].…”

Section: Introductionmentioning

confidence: 99%

Spontaneous diffusiophoretic separation in paper-based microfluidic device

Lee

Kim

2020

Micro and Nano Syst Lett

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Microfluidic paper-based analytical devices (μPADs) for separating particles have been playing a key role for point-ofcare diagnostics in the area of remote settings. While splendid separation methods using μPADs have been explosively developed, they still require external devices inducing external field. In this work, the spontaneous separation method in μPADs was suggested by leveraging convective flow (the imbibition of paper and nanoporous medium) and diffusiophoresis by ion exchange medium. Especially, the paper's fast imbibition was utilized as driving particles at the first stage, which results in fast overall processing in contrast to the spontaneous separation method of microfluidic chip integrated with only ion exchange medium. Therefore, our novel spontaneous selective preconcentration method based on μPADs would have key potential to be used in portable point-of-care devices in remote settings.

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“…Label-free biosensors have various benefits; they are low-cost point-of-care diagnostic devices with high sensitivity. Therefore, we used interdigitated microelectrodes (IME) as an electrical sensing platform 32 . A two-stage approach provided a locally analyte-concentrated area for sensing, and the label-free biosensors detect the highly concentrated analytes after biomarker preconcentration.…”

Section: Introductionmentioning

confidence: 99%

An Enhanced Platform to Analyse Low-Affinity Amyloid β Protein by Integration of Electrical Detection and Preconcentrator

Yoo

Yoon

Kim

et al. 2017

Sci Rep

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Sensitivity and limit of detection (LOD) enhancement are essential criteria for the development of ultrasensitive molecular sensors. Although various sensor types have been investigated to enhance sensitivity and LOD, analyte detection and its quantification are still challenging, particularly for protein-protein interactions with low association constants. To solve this problem, here, we used ion concentration polarization (ICP)-based preconcentration to increase the local concentration of analytes in a microfluidic platform for LOD improvement. This was the first demonstration of a microfluidic device with an integrated ICP preconcentrator and interdigitated microelectrode (IME) sensor to detect small changes in surface binding between antigens and antibodies. We detected the amyloid beta (Aβ) protein, an Alzheimer’s disease marker, with low binding affinity to its antibodies by adopting ICP preconcentration phenomena. We demonstrated that a combination of ICP preconcentrator and IME sensor increased the LOD by 13.8-fold to femtomolar level (8.15 fM), which corresponds to a significant advance for clinical applications.

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Capillarity ion concentration polarization for spontaneous biomolecular preconcentration mechanism

Cited by 36 publications

References 57 publications

A review: applications of ion transport in micro‐nanofluidic systems based on ion concentration polarization

A review: applications of ion transport in micro‐nanofluidic systems based on ion concentration polarization

Spontaneous diffusiophoretic separation in paper-based microfluidic device

An Enhanced Platform to Analyse Low-Affinity Amyloid β Protein by Integration of Electrical Detection and Preconcentrator

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