Developing synthetic conical nanopores for biosensing applications.
about
Nanopore-based analysis of biochemical speciesNanoporous membranes for medical and biological applications.A light transmission technique for pore size measurement in track-etched membranesBuilding bio-inspired artificial functional nanochannels: from symmetric to asymmetric modification.Synthetic molecular evolution of pore-forming peptides by iterative combinatorial library screening.Dynamic control of nanoprecipitation in a nanopipette.Advances in Resistive Pulse Sensors: Devices bridging the void between molecular and microscopic detectionDetermining the mechanism of membrane permeabilizing peptides: identification of potent, equilibrium pore-formersEnhanced translocation of single DNA molecules through alpha-hemolysin nanopores by manipulation of internal chargeLabel-free biosensing with functionalized nanopipette probes.Resistive-pulse measurements with nanopipettes: detection of Au nanoparticles and nanoparticle-bound anti-peanut IgYEngineered voltage-responsive nanopores.Analysis of single nucleic acid molecules with protein nanoporesBiomimetic smart nanopores and nanochannels.Construction of biomimetic smart nanochannels with polymer membranes and application in energy conversion systems.Bioinspired ion-transport properties of solid-state single nanochannels and their applications in sensing.Protein detection by nanopores equipped with aptamers.Applications of tunable resistive pulse sensing.Multiscale modeling of a rectifying bipolar nanopore: explicit-water versus implicit-water simulations.Multiscale modeling of a rectifying bipolar nanopore: Comparing Poisson-Nernst-Planck to Monte Carlo.Tunable resistive pulse sensing: potential applications in nanomedicine.A bidirection-adjustable ionic current rectification system based on a biconical micro-channel.Emerging tools for studying single entity electrochemistry.DNAzyme tunable lead(II) gating based on ion-track etched conical nanochannels.Voltage-gated ion transport through semiconducting conical nanopores formed by metal nanoparticle-assisted plasma etching.Magnetic microbead transport during resistive pulse sensing.Resistive pulse sensing of magnetic beads and supraparticle structures using tunable pores.Fabrication of nanofluidic diodes with polymer nanopores modified by atomic layer deposition.A biomimetic mercury(II)-gated single nanochannel.Simulation of a model nanopore sensor: Ion competition underlies device behavior.Probing the size of proteins with glass nanopores.Conductance-based profiling of nanopores: Accommodating fabrication irregularities.Scanning ion conductance microscopy mapping of tunable nanopore membranes.Protein detection using tunable pores: resistive pulses and current rectification.Adenosine-Activated Nanochannels Inspired by G-Protein-Coupled Receptors.Observations of the effect of confined space on fluorescence and diffusion properties of molecules in single conical nanopore channels.Maximizing ion current rectification in a bipolar conical nanopore fluidic diode using optimum junction location.Influence of electroosmotic flow on the ionic current rectification in a pH-regulated, conical nanopore.A tunable nanopore sensor for the detection of metal ions using translocation velocity and biphasic pulses.A method to tune the ionic current rectification of track-etched nanopores by using surfactant.
P2860
Q26751324-6BA4B6B0-AE89-4AA1-9E53-7DF7B4BE4C49Q27693240-FAAC994D-8AAF-429E-817F-36E95E842BFDQ28301075-EFC3932D-E07F-487E-801B-C61FA9A1825EQ34268338-675834C7-13C8-4B62-A400-29058364E496Q34581262-334A2FA3-70FF-4443-8F82-66E3AE4768EBQ34866352-34AED5C9-5F5A-4A8A-8D48-7BD59EDC4355Q35424882-47110E28-FF86-4646-B21C-2265A95C1E75Q36191769-B197B9D0-CC55-499D-B120-6145E97A54F1Q37018765-6DEBD7DD-DE56-4C26-AC48-A34610788E84Q37118884-FEFD3894-AE18-4F1E-9021-963E1CB2BB30Q37122659-AA1276E4-9ADE-4903-A7E4-757671AF8BCFQ37697552-50DF8C1C-070E-4A6C-8948-A2B8C1BE9FAFQ37772272-E4507A49-910A-4486-91D5-2A2A34C3CC3AQ37838728-2073EB3B-40AD-4E39-B4A4-BD02FEDD6D85Q37983981-80EA7CB3-52D1-409E-9920-BE16E0B1AE95Q38020154-2DA310BD-C9A7-4EC6-BC0E-6EA77F7742C2Q38328878-824F0C51-265E-4ABE-948E-138CA5A6F0F5Q38367510-7D353173-3A65-47D6-AA60-6E13526A5DBEQ38705116-54668B17-C785-4A12-ACD4-3FB883658453Q38847964-C20E5055-0925-40BC-886D-F512A81B1936Q38915342-5EB14C84-A821-49A1-BBC2-BC715CC91EEBQ38967253-48975DE4-8F95-4FFF-A6F9-AF910CEB93A9Q40548468-2BEFD6C3-9369-4217-A874-8FE9835BB1B7Q41308326-2F4B93F2-85F2-4A63-BA25-8D384A48F9ECQ41393154-B0FB0F98-3270-4A47-B60C-653C014CE2ECQ41860937-151E99A6-EAED-4A41-B999-FDAFF52FE616Q41967349-FCE3D3B2-B029-4B8D-8594-75D2D59917F1Q42199199-05066460-15EE-4349-BE95-1C00B8CD1FFDQ44299439-6B9DDE7A-886D-4D57-86FF-21FD8992C739Q47209387-5885234D-28EF-4725-9AEC-CC645E14735BQ47429574-272C5860-27F5-4A8B-A213-3AEA868D750CQ47611210-EC5683D7-8B4F-4217-85E3-C698E5FD15B7Q48262314-0301FC39-EA93-4A52-AE9B-734D96AF72AAQ48312475-7A292832-1AF2-4227-8A87-4EFDDC1CC523Q50428922-52A3EA89-BBD6-4844-B3B9-3E964C475EC7Q50541435-E32FB875-6B88-40D1-8B2A-F2B10ABBDF4BQ50575876-1DE986CE-12F0-4D6C-85BE-8126F28A46BEQ50871855-E0BF6EE8-E9F9-49B7-8F95-ED0AC5693EFFQ51071409-8617426A-DE3A-438F-86D3-03B4A0E7AA8BQ51642173-C74C5FA4-EDF8-489C-AABF-9237CB722717
P2860
Developing synthetic conical nanopores for biosensing applications.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Developing synthetic conical nanopores for biosensing applications.
@en
type
label
Developing synthetic conical nanopores for biosensing applications.
@en
prefLabel
Developing synthetic conical nanopores for biosensing applications.
@en
P2093
P356
P1433
P1476
Developing synthetic conical nanopores for biosensing applications.
@en
P2093
Charles R Martin
Lindsay T Sexton
Lloyd P Horne
P304
P356
10.1039/B708725J
P577
2007-09-03T00:00:00Z