Ultrafast immunoassays by coupling dielectrophoretic biomarker enrichment in nanoslit channel with electrochemical detection on graphene

Sanghavi, Bankim J.; Varhue, Walter; Rohani, Ali Haeri; Liao, Kuo-Tang; Bazydlo, Lindsay A.L.; Chou, Chia-Fu; Swami, Nathan S.

doi:10.1039/c5lc00840a

Cited by 85 publications

(57 citation statements)

References 46 publications

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“…In fact, our prior work quantified this at 10 4 -10 5 -fold concentration enhancement in the preconcentration region 19 and $10 3 -fold enhancement in analyte binding at capture probe surface. 22,23 This is apparent from the sharp rise in fluorescence signal to saturation levels in Figure 4 . (iii)).…”

Section: F Validation Using Spatio-temporal Biomarker Profilesmentioning

confidence: 85%

“…Our prior work has implemented this methodology within various sensing paradigms for improving biomarker sensitivity. 22,23 A cross-section view of the device geometry used within this work is schematically presented in Figure 1(a) (device images in S1, supplementary material), wherein glassy carbon modified Pt electrodes within the reservoirs leading to a microchannel on each side are used to initiate the discussed electrokinetic effects under a DC-offset (2 V/cm) AC field (70 V rms /cm) that is set at the critical frequency required to cause optimal biomarker nDEP, which is 1 MHz for streptavidin, 3 MHz for Neuropeptide Y (NPY), 22 and 4-6 MHz for Prostate Specific Antigen (PSA). 23 The microchannels (5 lm depth) are connected by slit-shaped channels of 200 nm depth (henceforth called nanoslit).…”

Section: Resultsmentioning

confidence: 99%

“…22,23 A cross-section view of the device geometry used within this work is schematically presented in Figure 1(a) (device images in S1, supplementary material), wherein glassy carbon modified Pt electrodes within the reservoirs leading to a microchannel on each side are used to initiate the discussed electrokinetic effects under a DC-offset (2 V/cm) AC field (70 V rms /cm) that is set at the critical frequency required to cause optimal biomarker nDEP, which is 1 MHz for streptavidin, 3 MHz for Neuropeptide Y (NPY), 22 and 4-6 MHz for Prostate Specific Antigen (PSA). 23 The microchannels (5 lm depth) are connected by slit-shaped channels of 200 nm depth (henceforth called nanoslit). Within each nanoslit (300 lm length/200 nm depth), a lateral constriction (optimized at 300 nm length and 40 nm gap) with a sharp surface charge non-uniformity is used to initiate ICP (see magnified top-view in Figure 1(b)), whereas no significant ICP occurs at the micro/ nanochannel interface due to the wide nanoslit entry points (30 lm width).…”

Section: Resultsmentioning

confidence: 99%

“…[20][21][22][23] Furthermore, the highly localized nature of DEP behavior, due to its dependence on rE 2 , limits its spatial extent. 13,24 Herein, by initiating ICP at lateral perm-selective constrictions of large surface charge non-uniformity, we create conductivity differences across the nanoslit length to enhance the spatial extent for biomarker depletion.…”

Section: Introductionmentioning

confidence: 99%

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Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

et al. 2016

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Selective and rapid enrichment of biomolecules is of great interest for biomarker discovery, protein crystallization, and in biosensing for speeding assay kinetics and reducing signal interferences. The current state of the art is based on DC electrokinetics, wherein localized ion depletion at the microchannel to nanochannel interface is used to enhance electric fields, and the resulting biomarker electromigration is balanced against electro-osmosis in the microchannel to cause high degrees of biomarker enrichment. However, biomarker enrichment is not selective, and the levels fall off within physiological media of high conductivity, due to a reduction in ion concentration polarization and electro-osmosis effects. Herein, we present a methodology for coupling AC electrokinetics with ion concentration polarization effects in nanoslits under DC fields, for enabling ultrafast biomarker enrichment in physiological media. Using AC fields at the critical frequency necessary for negative dielectrophoresis of the biomarker of interest, along with a critical offset DC field to create proximal ion accumulation and depletion regions along the perm-selective region inside a nanoslit, we enhance the localized field and field gradient to enable biomarker enrichment over a wide spatial extent along the nanoslit length. While enrichment under DC electrokinetics relies solely on ion depletion to enhance fields, this AC electrokinetic mechanism utilizes ion depletion as well as ion accumulation regions to enhance the field and its gradient. Hence, biomarker enrichment continues to be substantial in spite of the steady drop in nanostructure perm-selectivity within physiological media. Published by AIP Publishing. [http://dx

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Section: F Validation Using Spatio-temporal Biomarker Profilesmentioning

confidence: 85%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

et al. 2016

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“…These techniques have been widely applied in trapping, characterizing and separating particles [1].Using electrical fields is very suitable for the precise control of bioparticles like bacteria [2], yeast, apoptosis, viruses, proteins [3] and DNA due to some advantages of good controllability, easy operation, high efficiency and small damage to the particles [1].…”

Section: Introductionmentioning

confidence: 99%

Quantifying Particle Motion under Force Fields in Microfluidic Systems by Image Tracking Methods

Chen¹

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Micro-engineered devices for selective cell separation and analysis are of great importance in biomedical research. Dielectrophoresis (DEP), which enables the frequencyselective translation of particles under spatially non-uniform fields based on their distinctive impedance characteristics, is an effective technique for cell sorting and quantification. It has been used for selective manipulation and identification of microorganisms and cells. Particle translation towards or away from localized regions of high field occurs, respectively, under positive DEP (p-DEP) or negative DEP (n-DEP). In this manner, based on differences in polarization between different cells and the surrounding medium, non-destructive and label-free cell separations can be accomplished.This work is focused on using image analysis methods to quantify the translation of particles under spatially non-uniform fields to determine the DEP force spectrum versus frequency, within two different device designs. The first is based on a constricted microfluidic channel, wherein image tracking is used to directly identify particle translation, to quantify the DEP frequency spectra with single-particle sensitivity. The second is a set of microfluidic wells with ring electrodes, wherein the focus is on rapid quantification of DEP spectra, based on spatio-temporal analysis of light scattering due to particle translation.These techniques are applied to three kinds of bioparticles, Cryptosporidium parvum, Clostridium difficile and Human Embryonic Kidney (HEK) cell as subjects to validate a model for particles of different sizes and shapes.These methods could serve as useful tools to study cellular subpopulations, which is of fundamental importance in biomedical sciences.

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High‐Throughput Screening of Metabolic Biomarkers and Wearable Biosensors for the Quantification of Metabolites

Zhang

Qian

2023

Advanced Sensor Research

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Metabolic biomarkers facilitate pathological/physiological investigations and clinic decisions. Noninvasive quantification of metabolic biomarkers allows patients to monitor their health without time, location, and environmental constraints. Recently, the synergistic integration between high-throughput screening strategy via mass spectrometry and noninvasive quantification techniques via wearable biosensors may provide fundamental insights into the application of metabolic biomarkers in clinical diagnostics. Here, mass spectrometry for the screening of metabolic biomarkers in several major clinical diseases (retinoblastoma, coronary heart disease, lung adenocarcinoma) is introduced. Then, three types of wearable biosensors based on electrochemistry, organic electrochemical transistors, and field effect transistors for the noninvasive quantification of metabolic biomarkers are summarized. The review may serve as a handbook for high-throughput screening of metabolic biomarkers and wearable biosensors for the quantification of metabolites. It is anticipated that biomarker discovery and quantification will facilitate the next generation of wearable biosensors toward personalized, intelligent, and precise home-healthcare on a large-scale.

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Ultrafast immunoassays by coupling dielectrophoretic biomarker enrichment in nanoslit channel with electrochemical detection on graphene

Cited by 85 publications

References 46 publications

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

Nanoslit design for ion conductivity gradient enhanced dielectrophoresis for ultrafast biomarker enrichment in physiological media

Quantifying Particle Motion under Force Fields in Microfluidic Systems by Image Tracking Methods

High‐Throughput Screening of Metabolic Biomarkers and Wearable Biosensors for the Quantification of Metabolites

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