Trapping of proteins under physiological conditions in a nanopipette.
about
Transitioning Streaming to Trapping in DC Insulator-based Dielectrophoresis for BiomoleculesNano-constriction device for rapid protein preconcentration in physiological media through a balance of electrokinetic forces.Scaling down constriction-based (electrodeless) dielectrophoresis devices for trapping nanoscale bioparticles in physiological media of high-conductivity.Hydrodynamic trapping of molecules in lipid bilayers.Integrated sorting, concentration and real time PCR based detection system for sensitive detection of microorganismsInterference-Free Detection of Genetic Biomarkers Using Synthetic Dipole-Facilitated Nanopore Dielectrophoresis.Temporal and spatial temperature measurement in insulator-based dielectrophoretic devices.Functionalized nanopipettes: toward label-free, single cell biosensors.Ultrasensitive mycotoxin detection by STING sensors.Voltage-controlled metal binding on polyelectrolyte-functionalized nanoporesReversible thrombin detection by aptamer functionalized STING sensors.Quantification of pH gradients and implications in insulator-based dielectrophoresis of biomolecules.Immunoglobulin G and bovine serum albumin streaming dielectrophoresis in a microfluidic device.Nanotechnology for early cancer detection.Protein dielectrophoresis and the link to dielectric properties.Characterization of microparticle separation utilizing electrokinesis within an electrodeless dielectrophoresis chip.Method of creating a nanopore-terminated probe for single-molecule enantiomer discrimination.Label-free biosensing with functionalized nanopipette probes.Dielectrophoretic monitoring of microorganisms in environmental applications.Scanning ion conductance microscopy for studying biological samples.Electrodeless dielectrophoresis for bioanalysis: theory, devices and applications.Dielectrophoretic applications for disease diagnostics using lab-on-a-chip platforms.Microarray dot electrodes utilizing dielectrophoresis for cell characterization.Modeling of dielectrophoretic transport of myoglobin molecules in microchannels.AC-dielectrophoretic characterization and separation of submicron and micron particles using sidewall AgPDMS electrodes.Device for dielectrophoretic separation and collection of nanoparticles and DNA under high conductance conditions.Integrated dielectrophoretic and surface plasmonic platform for million-fold improvement in the detection of fluorescent events.Nano-electromanipulation of spin crossover nanorods: towards switchable nanoelectronic devices.Surface conductivity of biological macromolecules measured by nanopipette dielectrophoresis.Direct current dielectrophoretic simulation of proteins using an array of circular insulating posts.Dielectrophoresis force spectroscopy for colloidal clusters.A low voltage nanopipette dielectrophoretic device for rapid entrapment of nanoparticles and exosomes extracted from plasma of healthy donors.Multifunctional scanning ion conductance microscopy.Nanopipettes as Monitoring Probes for the Single Living Cell: State of the Art and Future Directions in Molecular Biology.Comment on “Trapping Single Molecules by Dielectrophoresis”
P2860
Q30417049-742C1E71-13FB-4FA2-89CC-2456AA1352ECQ30455840-A35EC15E-EEAF-4F4A-A055-D2894F33F35BQ30456496-3846B2E2-C404-4F07-A5F5-57463A47C006Q30459721-C6FE1CC2-8545-4105-AB51-D63DD3442CDAQ30557487-1E61201C-108E-464F-8D98-D37679DC5A99Q33709360-F43E3A5F-F8EB-463B-9813-4DA03AA7D7CFQ33847670-302020F9-9D4B-4954-AFCC-3AF0A46126D8Q34054654-CE9D4961-55EC-4856-8E82-E222FE60B13DQ34158801-4FDA5ED4-FE86-4CA4-8A20-87E45C8F1D89Q34996821-FEC56960-9FC3-4B4B-A26F-6203AF40E33AQ35061770-C15315C2-0EAE-4739-84E7-D4FB60410A6EQ35579396-0FC900F6-8FAB-4D26-9CDC-F607891D02FBQ35622510-DDBE63C4-6811-48E2-91A0-CD6D4368ABABQ35727150-50EB7C3C-CABB-4C9A-89FA-7319D5818238Q36025919-1501F56E-AB01-44D3-AF6B-056A24DFF070Q36858089-F8C9F453-072E-4AB9-9495-17246AF57765Q37096780-62329EF5-734A-4BB8-8A35-1B5860E3D04EQ37118884-7586E87D-BF8D-4C3E-8792-CE98F8EBED67Q37913247-7A93D0EE-4DFB-4829-B292-D95F16C3653BQ38064266-A127C1A3-CAB4-4477-8DE3-E779A58F5FF2Q38077709-43A2E57F-A361-4C2E-8A52-D61A07462BE4Q38837244-FF664299-C32B-4009-A040-46D6FFFFD80AQ41948994-96B81AC6-5C5A-4AFC-98DF-B1FC50F849A5Q42145844-370AA457-E852-4AA0-8DB8-3CD93D7BDC0DQ42182589-0946BA0D-63A5-463B-B5B2-564B2F723869Q45948588-70B47D5B-18FF-4FD2-BFD8-6F198B07F8B6Q47721541-A8DED678-74E0-4FAA-B86E-7EC9CD2CDA08Q50917148-9662AC90-63BD-41C2-A7A9-79952FBCB08CQ50942789-54CFCD9C-7936-43B3-9280-8E40EBB32D8DQ51536244-1FC575EC-7B16-4993-9558-EBDBB78927C3Q53364510-A99F4BEC-E121-4E17-B51B-6972340090CDQ54963994-0FDCD1EC-C350-456B-A02E-BDC6AF6FAC6DQ55034442-108E89D6-F532-421C-8157-EA9B4159938CQ55489913-DA9396B6-3A23-44FB-A147-D1A0C042487BQ56833536-413509C8-DDCD-4C2D-951A-6F43710154CE
P2860
Trapping of proteins under physiological conditions in a nanopipette.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh-hant
name
Trapping of proteins under physiological conditions in a nanopipette.
@en
Trapping of proteins under physiological conditions in a nanopipette.
@en-gb
Trapping of proteins under physiological conditions in a nanopipette.
@nl
type
label
Trapping of proteins under physiological conditions in a nanopipette.
@en
Trapping of proteins under physiological conditions in a nanopipette.
@en-gb
Trapping of proteins under physiological conditions in a nanopipette.
@nl
prefLabel
Trapping of proteins under physiological conditions in a nanopipette.
@en
Trapping of proteins under physiological conditions in a nanopipette.
@en-gb
Trapping of proteins under physiological conditions in a nanopipette.
@nl
P50
P356
P1476
Trapping of proteins under physiological conditions in a nanopipette.
@en
P2093
Samuel S White
P2860
P304
P356
10.1002/ANIE.200500196
P407
P577
2005-06-01T00:00:00Z