about
Chemical analysis of single cells.Nanoelectrodes for determination of reactive oxygen and nitrogen species inside murine macrophagesNanoscale mechanism of molecular transport through the nuclear pore complex as studied by scanning electrochemical microscopyAdvanced electroanalytical chemistry at nanoelectrodes.Fabrication of functional micro- and nanoneedle electrodes using a carbon nanotube template and electrodeposition.Biofunctionalized nanoneedles for the direct and site-selective delivery of probes into living cells.Stabilizing nanometer scale tip-to-substrate gaps in scanning electrochemical microscopy using an isothermal chamber for thermal drift suppression.Recent advances in the development and application of nanoelectrodes.Topographical and electrochemical nanoscale imaging of living cells using voltage-switching mode scanning electrochemical microscopyElectrical detection of specific versus non-specific binding events in breast cancer cells.Nanowires precisely grown on the ends of microwire electrodes permit the recording of intracellular action potentials within deeper neural structures.Nanoscale live-cell imaging using hopping probe ion conductance microscopy.Nanokit for single-cell electrochemical analysesElectrochemical Sensing and Imaging Based on Ion Transfer at Liquid/Liquid Interfaces.Nanopipette exploring nanoworld.Nanoneedle: a multifunctional tool for biological studies in living cells.Electrochemistry in nanoscopic volumes.Single cell analysis at the nanoscale.One-dimensional nanoprobes for single-cell studies.Sensing cisplatin-induced permeation of single live human bladder cancer cells by scanning electrochemical microscopy.Carbon nanoelectrodes for single-cell probing.Alkylene-bridged viologen dendrimers: versatile cell delivery tools with biosensing properties.Electrical detection of cellular penetration during microinjection with carbon nanopipettes.Real-time Monitoring of Discrete Synaptic Release Events and Excitatory Potentials within Self-reconstructed Neuromuscular Junctions.Methods to Measure Water Permeability.Electrochemical detection of receptor-mediated endocytosis by scanning electrochemical microscopy.Novel electrochemical method of fast and reproducible fabrication of metallic nanoelectrodes.Microelectrochemical visualization of oxygen consumption of single living cells.Perfusion double-channel micropipette probes for oxygen flux mapping with single-cell resolution.Novel method for rapid toxicity screening of magnetic nanoparticles.Lab-on-a-Tip (LOT): Where Nanotechnology Can Revolutionize Fibre Optics.A high spatiotemporal study of somatic exocytosis with scanning electrochemical microscopy and nanoITIES electrodes.Nanoelectrode for Amperometric Monitoring of Individual Vesicular Exocytosis Inside Single SynapsesScanning electrochemical microscopy in the 21st century. Update 1: five years afterThe Expanding Role of Vesicles Containing AquaporinsApproximate Analytical Solution of Nonlinear Reaction’s Diffusion Equation at Conducting Polymer UltramicroelectrodesNanoscale intermittent contact-scanning electrochemical microscopy
P2860
Q30466574-8F4D03C9-5343-49FE-B356-8DD6DC90C45AQ30523390-8CEF5088-099A-44DC-A968-E475187DB68FQ30535755-7B884888-99ED-4DE9-8067-2FDF7138933DQ33636142-A6ADF465-98A1-49F9-841F-8BFA3E1FDECDQ33945010-272FA218-40AB-45A5-9EEB-995157CDDFD2Q34166483-37FFB960-B75D-4D24-9151-6734A66B5D49Q35894956-E46E2591-AD49-4834-A4A9-5F30A8AF412CQ36100653-F0C95B40-7812-4A5D-A008-3255D511FFC5Q36122900-EE27EB69-5FC7-4D07-9A81-0F8DD1A7D1EEQ36961257-759A35F6-F53B-42CF-9EC1-E30047CFBD3AQ37174863-C7CB4273-B985-42C6-BDA9-7C7071365032Q37242814-8BD99808-34E4-4E14-A077-B9865071E3BEQ37346922-DF73A83F-FC03-46D8-B467-26B12AB88659Q37398642-70FBF2F5-31EE-4CAC-B8CD-A73A104F2219Q37610330-2BA300D6-837D-4124-B6DD-A1106232EA39Q37774263-E3C822B8-B96B-4190-8A89-3D89F4B4B672Q37802224-87B29C01-0ADF-4E5D-97C0-7B540399FE45Q37963772-8E100532-3C0F-4C74-82BC-44B796D2357BQ38172636-7C2B9E06-4A76-4853-AD25-A7C3BD4A3349Q38851041-11823B8A-E637-4BE3-A531-73E85EA10A58Q38886854-CD716D05-2B82-4784-90B5-263C795BA95EQ38946033-36190AB8-CE0A-4058-BA08-6D3A47CFE0E4Q38991703-4A5FE789-CA59-4FBD-9E15-7CC742E8B252Q48126530-13C4EFB8-2AE2-4C6E-9138-1FCE172FA7A7Q51112277-FAA6CBA6-1718-4882-BCD5-3A4A635E1532Q51765886-F2B1BB43-F5E3-4D2C-90C9-E34F7545CD27Q53427902-82703011-3E5B-4239-9D68-D31D6E0D933BQ54327738-5DE014F7-EC8C-44A9-BC21-0F0924E75E41Q55039340-FB0BFDFE-232D-430C-A74C-C2753415FF82Q55040491-F0AA7C33-749D-426B-A597-3B02C53422B7Q55289066-A37B9855-FA7A-485A-A24F-000766D36FBBQ55338888-FA143A67-7BC2-4123-8224-7A9DF5FC64BAQ57391541-D78B3EBD-0C2E-492E-8C8E-7BED2BE9517FQ58220999-CD9AC12D-EE57-441B-A8FA-DFC3ED588222Q58579310-6828B8B9-76D1-45E9-9C54-4453450B9EFDQ58692209-DEEEF292-9A9E-45AF-88A1-36821C1F63C3Q59157349-4E5153B4-19EF-43C1-8C61-98C9000E9F49
P2860
description
2008 nî lūn-bûn
@nan
2008 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2008 թվականի հունվարին հրատարակված գիտական հոդված
@hy
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
name
Nanoelectrochemistry of mammalian cells
@ast
Nanoelectrochemistry of mammalian cells
@en
Nanoelectrochemistry of mammalian cells.
@nl
type
label
Nanoelectrochemistry of mammalian cells
@ast
Nanoelectrochemistry of mammalian cells
@en
Nanoelectrochemistry of mammalian cells.
@nl
prefLabel
Nanoelectrochemistry of mammalian cells
@ast
Nanoelectrochemistry of mammalian cells
@en
Nanoelectrochemistry of mammalian cells.
@nl
P2093
P2860
P356
P1476
Nanoelectrochemistry of mammalian cells
@en
P2093
François O Laforge
James Carpino
Michael V Mirkin
Susan A Rotenberg
Thushara P Abeyweera
P2860
P304
P356
10.1073/PNAS.0711075105
P407
P577
2008-01-04T00:00:00Z