Pre-binding dynamic range and sensitivity enhancement for immuno-sensors using nanofluidic preconcentrator.
about
Ultrafast immunoassays by coupling dielectrophoretic biomarker enrichment in nanoslit channel with electrochemical detection on graphene.Multiplexed proteomic sample preconcentration device using surface-patterned ion-selective membrane.Capillary-valve-based fabrication of ion-selective membrane junction for electrokinetic sample preconcentration in PDMS chipNanopore-induced spontaneous concentration for optofluidic sensing and particle assembly.Capillarity ion concentration polarization for spontaneous biomolecular preconcentration mechanismBattery operated preconcentration-assisted lateral flow assay.Stabilization of ion concentration polarization using a heterogeneous nanoporous junction.Increasing the sensitivity of enzyme-linked immunosorbent assay using multiplexed electrokinetic concentrator.Detecting kinase activities from single cell lysate using concentration-enhanced mobility shift assayNanofracture on fused silica microchannel for Donnan exclusion based electrokinetic stacking of biomolecules.High yield sample preconcentration using a highly ion-conductive charge-selective polymer.Continuous signal enhancement for sensitive aptamer affinity probe electrophoresis assay using electrokinetic concentration.Real-time dual-loop electric current measurement for label-free nanofluidic preconcentration chip.Preconcentration of diluted mixed-species samples following separation and collection in a micro-nanofluidic device.Review article: Fabrication of nanofluidic devicesOn the propagation of concentration polarization from microchannel-nanochannel interfaces. Part II: Numerical and experimental study.Characterization of microparticle separation utilizing electrokinesis within an electrodeless dielectrophoresis chip.Protein immobilization techniques for microfluidic assaysDevice considerations for development of conductance-based biosensors.Nanofluidic concentration devices for biomolecules utilizing ion concentration polarization: theory, fabrication, and applications.Continuous separation of colloidal particles using dielectrophoresis.Nanofluidics in point of care applications.Enhancing protease activity assay in droplet-based microfluidics using a biomolecule concentrator.Active accumulation of very diluted biomolecules by nano-dispensing for easy detection below the femtomolar range.Cracking-assisted fabrication of nanoscale patterns for micro/nanotechnological applications.Stabilization of ion concentration polarization layer using micro fin structure for high-throughput applications.Effects of constant voltage on time evolution of propagating concentration polarization.Applications and theory of electrokinetic enrichment in micro-nanofluidic chips.Microfluidic concentration-enhanced cellular kinase activity assay.Rapid quantification of disease-marker proteins using continuous-flow immunoseparation in a nanosieve fluidic device.High-throughput cell and particle characterization using isodielectric separation.Concurrent DNA Preconcentration and Separation in Bipolar Electrode-Based Microfluidic Device.Nafion Film Based Micro-nanofluidic Device for Concurrent DNA Preconcentration and Separation in Free Solution.Amplified electrokinetic response by concentration polarization near nanofluidic channel.The effect of the surface functionalization and the electrolyte concentration on the electrical conductance of silica nanochannels.Enrichment of nanoparticles and bacteria using electroless and manual actuation modes of a bypass nanofluidic device.Concentration-enhanced rapid detection of human chorionic gonadotropin (hCG) on a Au surface using a nanofluidic preconcentratorStimuli-responsive reagent system for enabling microfluidic immunoassays with biomarker purification and enrichment.An Enhanced Platform to Analyse Low-Affinity Amyloid β Protein by Integration of Electrical Detection and Preconcentrator.Force fields of charged particles in micro-nanofluidic preconcentration systems.
P2860
Q30278475-73B11731-CD17-4C2D-8AE4-45BE529237C3Q30482036-CB3417F7-2855-495B-8CE5-62D85F2E04E7Q30496233-38173B17-6C28-4C75-871A-C05ECE4259E9Q30535255-A45E97D8-B62E-499C-9A59-11839A290724Q30696720-B770337E-47D7-416B-AF3F-7FB96D4AAB4BQ33455062-D26610C3-7DCC-4B0E-81E5-9F1324F44FACQ33591174-EB903926-F248-4D13-A2F5-B434FA793E2DQ33858150-AF56D418-3893-4951-94E8-7591221B07DCQ34089220-D55C4DF7-3FC6-4109-B58B-898BE2591CA3Q34333851-441547AC-3F88-420A-84E7-597C42F00A67Q35075133-3638B078-595D-48ED-B324-BA647E7B259BQ35231727-6E5D5082-BF06-4617-B972-9400F2A4D00CQ35395609-F6F5D09F-D205-4456-ACB9-26E4D0889265Q36599486-547871B4-762E-4D07-9FF9-5DA01591ECA4Q36728112-C59B4F1E-0A96-4D15-AF14-E8CE5133A094Q36752552-33633EC6-D7BF-4F1B-9D56-E2F7321DC121Q36858089-350E6B28-9FF0-4D82-8EE4-74EE823AB86BQ37106312-36BE089D-C51A-4D96-8DDC-E06376B6BE2AQ37696152-4BB3328C-CB86-4F4A-A3E8-46B5EADB0199Q37697521-0EDC1D8F-51F1-42AA-BF34-1B92087DEF1DQ38084228-7DDDA023-2AB3-4B1C-A495-8180AD8F3286Q38212161-7324170E-0A8D-4BEB-AFD1-15D0E8505358Q38280621-4EB0E39A-55BD-4961-9C40-5AAB7CDAE002Q38302981-1922D7B0-46B3-4EEC-9076-23632DD22290Q38675656-27B952F8-4F6D-4AC2-A227-48738C0E2FB7Q38944938-73A112AF-57F3-44B7-9BF3-DE2FC1289B8FQ39077624-C0D847B6-4F1B-47E3-A466-EDDFA1528ACDQ39212305-0423487F-674B-42FE-ABF1-4C6F03B615C7Q39805527-B4A4B861-1DD4-4C43-9B8E-3E47726381F9Q39816105-524043A7-EAD9-4669-B602-11DAA5C4FE66Q39878099-103F58C7-B4D0-4E14-828B-B74D8BEEB14BQ40845509-1B826028-CEC7-4CA2-9078-D860C79E725CQ41789876-1339FCF3-6AE6-4E91-9354-BA2F2A523745Q41987399-99631DE9-ED21-4412-8D2E-120342FDD01AQ42127322-653F785F-1C3A-45B4-B165-64FB932E2A8BQ42265433-B8A9F520-11B6-4BDC-BB32-9E034F4BF951Q42410428-BE81BE52-32DD-44CF-8CD8-589D93A84BBFQ43119384-CB46E1FD-EF29-4C4F-B83E-48B7FFC23E68Q45304694-BBD7749A-1213-4B3F-B152-ED8691136C3FQ47195476-F449556F-9C65-4C69-9A2C-EFE3B5B07259
P2860
Pre-binding dynamic range and sensitivity enhancement for immuno-sensors using nanofluidic preconcentrator.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@en
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@nl
type
label
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@en
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@nl
prefLabel
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@en
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@nl
P2860
P356
P1433
P1476
Pre-binding dynamic range and ...... g nanofluidic preconcentrator.
@en
P2093
Jongyoon Han
Ying-Chih Wang
P2860
P304
P356
10.1039/B717220F
P577
2008-01-14T00:00:00Z