about
Microtechnologies for studying the role of mechanics in axon growth and guidance.Low piconewton towing of CNS axons against diffusing and surface-bound repellents requires the inhibition of motor protein-associated pathways.Neuronal Cell Bodies Remotely Regulate Axonal Growth Response to Localized Netrin-1 Treatment via Second Messenger and DCC DynamicsHigh-resolution analysis of neuronal growth cone morphology by comparative atomic force and optical microscopy.Magnetic manipulation and optical imaging of an active plasmonic single-particle Fe-Au nanorod.Direct measurement of the forces between complementary strands of DNA.Advances in magnetic tweezers for single molecule and cell biophysics.In vitro study of the interaction of heregulin-functionalized magnetic-optical nanorods with MCF7 and MDA-MB-231 cells.Advances in affinity ligand-functionalized nanomaterials for biomagnetic separation.A microfluidic dual gradient generator for conducting cell-based drug combination assays.Micromagnet arrays for on-chip focusing, switching, and separation of superparamagnetic beads and single cells.Micromagnet arrays enable precise manipulation of individual biological analyte-superparamagnetic bead complexes for separation and sensing.Analysis of cell-cell contact mediated by Ig superfamily cell adhesion molecules.Flow enhanced non-linear magnetophoretic separation of beads based on magnetic susceptibility.Scanning tunnelling microscopy of Z-DNA.Bio-Nano-Magnetic Materials for Localized Mechanochemical Stimulation of Cell Growth and Death.Resistive pulse sensing of magnetic beads and supraparticle structures using tunable pores.Rapid, highly sensitive detection of herpes simplex virus-1 using multiple antigenic peptide-coated superparamagnetic beads.Neuron Subpopulations with Different Elongation Rates and DCC Dynamics Exhibit Distinct Responses to Isolated Netrin-1 Treatment.Probing the soybean Bowman-Birk inhibitor using recombinant antibody fragments.Synthesis of superparamagnetic particles with tunable morphologies: the role of nanoparticle-nanoparticle interactions.Mutation of the membrane-associated M1 protease APM1 results in distinct embryonic and seedling developmental defects in Arabidopsis.Creation of recombinant antigen-binding molecules derived from hybridomas secreting specific antibodies.Synthesis and characterization of paramagnetic microparticles through emulsion-templated free radical polymerization.Characterization of carboxylate nanoparticle adhesion with the fungal pathogen Candida albicans.Immunoassays in nanoliter volume reactors using fluorescent particle diffusometry.Traveling wave magnetophoresis for high resolution chip based separations.Magnetic tweezers measurement of the bond lifetime-force behavior of the IgG-protein A specific molecular interaction.Nanoliter-scale reactor arrays for biochemical sensing.Properties of mixed lipid monolayers assembled on hydrophobic surfaces through vesicle adsorption.Mesoporous membrane device for asymmetric biosensing.Flow-enhanced nonlinear magnetophoresis for high-resolution bioseparation.A biosensor based on magnetoresistance technology.Isolation of Bowman-Birk-Inhibitor from soybean extracts using novel peptide probes and high gradient magnetic separation.Mechanochemical stimulation of MCF7 cells with rod-shaped Fe-Au Janus particles induces cell death through paradoxical hyperactivation of ERK.Templated synthesis of gold–iron alloy nanoparticles using pulsed laser depositionStructure and dynamics of the fibronectin-III domains of Aplysia californica cell adhesion moleculesStructure, force, and energy of a double-stranded DNA oligonucleotide under tensile loadsHelical period of Z-DNAImplementation of force differentiation in the immunoassay
P50
Q26797395-FAA8F41E-31BA-4204-A089-7A5493B5CDD4Q30601245-F02B193B-30BD-4E3B-A6F0-B29B43A06B1CQ30833810-1D994D3E-0F2E-4A31-8CF8-DE46E5FC228CQ33261190-6A4F9DF0-684E-4360-BDFD-08FD118D26D1Q34064994-D84C7677-953F-4A18-BE98-D9983EC7AD05Q36728149-CDDE15E3-0C4B-4A38-B570-6C7E0AAFA7E3Q38164987-FFE1FCEB-E714-4FAE-882F-AAC0D9F20482Q38255361-4EE97963-398C-4F36-A383-92A3277D3E90Q38511542-9FD97FD3-D466-45C0-8080-D07C0289EC38Q38819479-8596A68E-51C0-4AE1-9D5F-758915F02F56Q38854681-5202195B-7F9B-43B2-B675-7BB692EDD243Q38932060-B1CAAAD8-2ABB-493E-BA8D-501964C00174Q39025613-2E84393D-375F-4A8C-BF97-A246B1247E0EQ39092655-E05363BD-ACBB-4A58-8056-33DCE99A7BA9Q39713267-D08229EE-C54A-4CAA-985C-B3565D4A409BQ41185176-05C3C675-086C-432E-91B7-EFDBC36848CFQ41967349-29271BA9-4132-4685-86F8-0E4DA0CFD4BCQ42185132-5E493FE2-731C-4AD9-BDC6-5DF246101E7CQ42479977-A82EE15C-D2A9-409E-9736-FEB318B7C4C9Q43765566-2F171CD0-5F8E-4FE9-829C-DEEC19B5D35DQ44917000-68E6AA5C-4F32-4694-82C9-28D8B5579348Q45966967-F85A002C-48D7-47A4-AE3B-7A9E8B3A0DE6Q46474062-45195E4E-D0AB-4ACC-AB58-E3021BEC7BF0Q46977161-58EAABDE-1B50-466E-BDA9-BC5E2A8FC220Q47667654-940C41DF-51E7-444D-9829-CBEBB220EAA9Q47895393-DE539162-6B9C-4727-85EC-951C221D54F9Q50858299-DFBC0F00-F212-4E8E-87C3-FFD1CFA3B79EQ51016550-99ED554D-71CE-4EB7-BB96-DD529DCE3230Q51157054-97571F8F-9491-496C-83FC-69B16DFA22ABQ51202207-86F1D4E9-9C14-4943-BFFD-3D18136158CCQ51543532-FC785069-A365-4927-A6BC-0F934AFE5006Q51577264-385E7706-B5DB-4C64-97CF-2D87D402D871Q51605325-BA321F30-237D-4E84-AB2A-6ADE78F909E9Q53257489-30496508-4D0A-4B47-A8DF-B79D63C348D2Q53420638-3E3F5498-00EC-4A98-AF11-F4925F69D045Q57624513-2407DABC-CD1C-4EE7-BB25-7BB212355698Q57951666-AF2888CE-C5B4-4A6F-91B7-92B39A742D7AQ58846683-BE70FFD5-2BA6-4071-AE76-36A130155727Q59010106-AF80709D-33B4-42EE-85DE-EA2E711C83CEQ73286676-D50165F9-20F7-4D6F-A752-583BDCD7E711
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Gil U Lee
@ast
Gil U Lee
@en
Gil U Lee
@es
Gil U Lee
@nl
Gil U Lee
@sl
type
label
Gil U Lee
@ast
Gil U Lee
@en
Gil U Lee
@es
Gil U Lee
@nl
Gil U Lee
@sl
prefLabel
Gil U Lee
@ast
Gil U Lee
@en
Gil U Lee
@es
Gil U Lee
@nl
Gil U Lee
@sl
P1053
P-8696-2016
P106
P21
P31
P3829
P496
0000-0002-7949-5848
P569
2000-01-01T00:00:00Z