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Superresolution microscopy reveals the three-dimensional organization of meiotic chromosome axes in intact Caenorhabditis elegans tissue.Postsynaptic actin regulates active zone spacing and glutamate receptor apposition at the Drosophila neuromuscular junction.Graphene-enabled electron microscopy and correlated super-resolution microscopy of wet cells.Dual-objective STORM reveals three-dimensional filament organization in the actin cytoskeleton.Translocation of interleukin-1β into a vesicle intermediate in autophagy-mediated secretionSpectrally Resolved, Functional Super-Resolution Microscopy Reveals Nanoscale Compositional Heterogeneity in Live-Cell Membranes.Direct Optical Visualization of Graphene and Its Nanoscale Defects on Transparent Substrates.Remodeling of ER-exit sites initiates a membrane supply pathway for autophagosome biogenesis.Development of a Virtual Cell Model to Predict Cell Response to Substrate Topography.Correlative Super-Resolution Microscopy: New Dimensions and New Opportunities.Spatially Resolved in Situ Reaction Dynamics of Graphene via Optical Microscopy.Cytoskeletal organization in microtentacles.Graphene visualizes the first water adlayers on mica at ambient conditions.COPII-coated membranes function as transport carriers of intracellular procollagen I.A 160-kilobit molecular electronic memory patterned at 10(11) bits per square centimetre.Ultrahigh-throughput single-molecule spectroscopy and spectrally resolved super-resolution microscopy.NuMA recruits dynein activity to microtubule minus-ends at mitosis.Wetting: Contact with what?Achieving the theoretical depairing current limit in superconducting nanomesh films.Atomic force microscopy characterization of room-temperature adlayers of small organic molecules through graphene templating.Scanning tunneling microscopy characterization of the electrical properties of wrinkles in exfoliated graphene monolayers.The microscopic structure of adsorbed water on hydrophobic surfaces under ambient conditions.Ground-state equilibrium thermodynamics and switching kinetics of bistable [2]rotaxanes switched in solution, polymer gels, and molecular electronic devices.A nanosized Y(2)O(3)-based catalytic chemiluminescent sensor for trimethylamine.The crossover from two dimensions to one dimension in granular electronic materials.Azidation of silicon(111) surfaces.Spectrally Resolved Super-Resolution Microscopy Unveils Multipath Reaction Pathways of Single Spiropyran Molecules.Long, highly-ordered high-temperature superconductor nanowire arrays.Deep nuclear invaginations are linked to cytoskeletal filaments - integrated bioimaging of epithelial cells in 3D culture.Rbfox Splicing Factors Promote Neuronal Maturation and Axon Initial Segment Assembly.Super-Resolution Microscopy Reveals the Native Ultrastructure of the Erythrocyte Cytoskeleton.Spectrally Resolved and Functional Super-resolution Microscopy via Ultrahigh-Throughput Single-Molecule Spectroscopy.Effect of Cell Sex on Uptake of Nanoparticles: The Overlooked Factor at the Nanobio Interface.Optical characterization of surface adlayers and their compositional demixing at the nanoscale.Asymmetrically Positioned Flagellar Control Units Regulate Human Sperm RotationThe Spectrin-Actin-Based Periodic Cytoskeleton as a Conserved Nanoscale Scaffold and Ruler of the Neural Stem Cell LineageTANGO1 and SEC12 are copackaged with procollagen I to facilitate the generation of large COPII carriersInformation-rich localization microscopy through machine learningMetabolic Reprogramming in Astrocytes Distinguishes Region-Specific Neuronal Susceptibility in Huntington MiceDirect comparison of clathrin-mediated endocytosis in budding and fission yeast reveals conserved and evolvable features
P50
Q33810396-9B76C4DF-CCF2-4096-8091-49F9E7FDC5CFQ34053827-B012C1F5-4C0F-4F06-9E6F-658AB3F3A8B2Q35814272-DC497421-FFBC-4190-8A1F-8BE80EDB6B45Q35832415-AB4FDDB6-A2D8-4E74-A80B-A25F0BF0436FQ36506015-09669A8B-6ECC-4107-98FE-66DF37C7ABA1Q38400440-6EA48A8B-1F19-4E82-9845-242901730F02Q38413111-9AEF277F-441F-4B22-9DD2-825DAC9A5F90Q38654396-DBC1F889-6819-43C5-8322-00E12173EA8CQ38662446-021B412F-9FC8-42E3-BB35-60D304BFDC76Q38775309-A7CC02CE-B7E8-4EB2-9E09-01CECF233855Q38853803-FED427F1-9436-4024-8791-9E9805857550Q41597783-82CD6260-3930-4092-9774-CF879FDA42E4Q44195950-5505C498-399B-470B-ADC9-BD1B68E0D0BFQ44943575-6F0DC5B0-1B93-4B64-83AC-4922AC34D58FQ45892758-0D0F8D3E-B82D-4838-84C5-8169B6F21A5EQ45932098-CF312487-23E9-4A8D-88CA-C53EF130C755Q45970921-80CB0468-2ADA-4548-92CB-E4C7EF333ACEQ45977224-0B4F668B-1CCC-471F-A6C1-576A55B21FA4Q46184410-9186F542-5E1D-4A8D-9E8F-7960C5195A18Q46196308-75266D48-D569-41E8-A3B7-A329413F8C9EQ46215816-1B28288F-F53A-4B66-A176-3296A6CD77CBQ46219074-C1A91165-3A65-497E-9CF5-03AAA7921D44Q46227433-65B2DB6D-5E8E-47FC-A6DE-695705F7673EQ46279491-C089FC6C-9F99-4260-8447-0E9B02F189DCQ46533842-0CB68B27-D3AD-484D-A6F4-E8A24F8EBA28Q46559099-04F521AE-3E1A-4E1F-AE20-BEECFAB2FC2BQ46972579-C2DAC2F1-F585-4FDB-AA5C-3ED20B9C323FQ47273129-DB39C134-6376-4E7C-B332-24877374E9AAQ48120657-412247D6-1FA0-4678-8BD1-B3B2036ACEDCQ49342236-82A93368-A364-485B-8FB7-8638FC74DEB2Q49547365-7EECFD20-9B53-460C-BB62-B181526D3BEAQ50005139-BC3CEFB7-09BB-4791-870A-B22EA6915BE0Q52726684-FABB2370-5764-4FFE-BCDD-4E276D282D5CQ55017317-39C9FEDD-0F49-429C-BDD7-C8C4F13E3733Q58764072-BFCC8016-E5DA-47D5-979A-181EBE5BA823Q58796846-1C60F28E-2B91-45DF-A182-3B2CD10FF47EQ60957482-66BEDDBE-FEB1-484D-A5A7-10E4007F7122Q64079904-2F789946-8E08-4DFC-BF35-0F984A38B21AQ64387394-9581BD3E-DA32-45A9-AD3A-7BD93F9980B0Q83225746-3785A2AD-31B0-44BD-81D9-5ABFF6A7D9D4
P50
description
researcher
@en
հետազոտող
@hy
name
Ke Xu
@ast
Ke Xu
@en
Ke Xu
@es
Ke Xu
@nl
Ke Xu
@sl
type
label
Ke Xu
@ast
Ke Xu
@en
Ke Xu
@es
Ke Xu
@nl
Ke Xu
@sl
prefLabel
Ke Xu
@ast
Ke Xu
@en
Ke Xu
@es
Ke Xu
@nl
Ke Xu
@sl
P1053
A-9476-2011
P106
P31
P3829
P496
0000-0002-2788-194X