about
Order and disorder in intermediate filament proteinsPhosphorylation-Induced Mechanical Regulation of Intrinsically Disordered Neurofilament Proteins.Formation of bacterial pilus-like nanofibres by designed minimalistic self-assembling peptides.Spontaneous structural transition in phospholipid-inspired aromatic phosphopeptide nanostructures.Liquid crystal assemblies in biologically inspired systems.A minimal length rigid helical peptide motif allows rational design of modular surfactants.Structures and interactions in 'bottlebrush' neurofilaments: the role of charged disordered proteins in forming hydrogel networks.Neurofilament assembly and function during neuronal development.Structural Effects of Single Mutations in a Filamentous Viral Capsid Across Multiple Length Scales.Modular Synthetic Approach for Adjusting the Disassembly Rates of Enzyme-Responsive Polymeric Micelles.Probing the interactions of intrinsically disordered proteins using nanoparticle tags.Structural flexibility of CaV1.2 and CaV2.2 I-II proximal linker fragments in solution.Metastability in lipid based particles exhibits temporally deterministic and controllable behavior.Cross polarization compatible dialysis chip.Gel-expanded to gel-condensed transition in neurofilament networks revealed by direct force measurements.Unconventional salt trend from soft to stiff in single neurofilament biopolymers.Correction to Structural Effects of Single Mutations in a Filamentous Viral Capsid Across Multiple Length Scales.The role of Vimentin in Regulating Cell Invasive Migration in Dense Cultures of Breast Carcinoma Cells.Entropic Phase Transitions with Stable Twisted Intermediates of Bio-Inspired Self-Assembly.Reversible Dimerization of Polymeric Amphiphiles Acts as a Molecular Switch of Enzymatic Degradability.Encapsulation and covalent binding of molecular payload in enzymatically activated micellar nanocarriers.Neurofilaments Function as Shock Absorbers: Compression Response Arising from Disordered Proteins.Loss of bottlebrush stiffness due to free polymers.Pathological transitions in myelin membranes driven by environmental and multiple sclerosis conditionsLiquid Crystals of Self-Assembled DNA BottlebrushesField-induced nodal order parameter in the tunneling spectrum ofYBa2Cu3O7−xsuperconductorDesign of Controllable Bio-Inspired Chiroptic Self-AssembliesTransition from a mixed to a pure d-wave symmetry in superconducting optimally doped YBa2Cu3O7-x thin films under applied fieldsDirty superconductivity in the electron-doped cuprate Pr(2-x)Ce(x)CuO(4-delta): tunneling studyOrigin of the anomalous low temperature upturn in the resistivity of the electron-doped cuprate superconductorsComposite bottlebrush mechanics: α-internexin fine-tunes neurofilament network propertiesEnzyme-responsive amphiphilic PEG-dendron hybrids and their assembly into smart micellar nanocarriersTransition of Metastable Cross-α Crystals into Cross-β Fibrils by β-Turn FlippingFunctional Coiled-Coil-like Assembly by Knob-into-Hole Packing of Single Heptad RepeatDeciphering the Rules for Amino Acid Co-Assembly Based on Interlayer DistancesUniversal and Accessible Entropy Estimation Using a Compression AlgorithmDelayed nucleation in lipid particlesSelf-Assembly of Aromatic Amino Acid Enantiomers into Supramolecular Materials of High RigidityNanoparticle Mobility over a Surface as a Probe for Weak Transient Disordered Peptide-Peptide Interactions
P50
Q28081207-133F9118-E15B-4F9F-957E-56992D5169C9Q30399956-34CB7665-DC91-4ACA-B923-B9168E549B35Q31142707-20B17FEE-BA7A-495B-9737-7DDE5C89014DQ35584886-6E4500BA-49C1-40CF-81FD-060A57F04F88Q37591036-2C0C331A-00CB-4E62-8FD2-1FC6C9A7B89AQ37591398-BB629EAD-30D7-4F27-B236-B607140781AAQ38044423-BB5B8C1F-1170-42C5-8BEA-5452E390299BQ38337684-DA639C1E-5F0C-4966-BE63-BAECEC280861Q38705070-9A3821E6-CFE2-4CB7-B04E-EA0F3C852615Q38925074-90D4287D-9B70-47B0-A946-9FD70B7A4128Q39023702-D28E0CE2-FD1B-4989-A400-48B0F224F6E2Q41540386-E72813C0-30FF-4C28-B385-301AEB678FB0Q41901916-85384498-5F64-414B-A833-B551503C250EQ42201060-32E53E70-F048-4B7F-B396-F809F70AD45DQ44685623-674548B3-3CE1-493E-AAE0-E5412E57CC40Q46722614-378119E8-4226-4F0F-8D83-EFE8081C64B3Q47567217-365B64D7-8A5A-446C-9A77-E80BD30864CDQ47664522-849E4D97-A817-467C-8CC3-F45FE7E5E4CBQ48101096-D5FE4D6F-FDD0-410B-AD8A-AFDCF34052E1Q48146239-B0143284-F8BF-4445-94B2-6288BBA90A80Q51016059-AFD5B7EE-B3D8-407B-8F2A-9424E4D2BB8BQ51394216-F9A892F1-CEE4-4D84-9C81-5FD7F7FE51CEQ51529332-26678CF8-23F9-448E-843E-696EF24DFD75Q57465762-0C91D220-C417-4C33-98DD-FF53010BF06DQ58002468-8E146D4B-40BB-4092-B5A8-B5C2966B0DF8Q59442739-73BC99B5-C5E9-4F25-9B37-91AFF0D0FE41Q62065784-03634121-2F23-4A96-9E34-AD44B793433CQ80332453-78B8794C-9685-4430-B39D-03920BDCB83CQ81427375-87A61595-B1B3-4899-95F2-8E4DE1BA3CA4Q81559226-65DF27D5-C95B-46CE-B50E-F6E2CDC41C60Q85434046-1CCA0571-439E-4144-9A10-6E2418AF71CEQ87356651-351B63DE-CA24-4BA1-B4DC-F3647E71AE90Q90378566-1DFC9089-0CC4-4828-9AC9-2DEBEBAE8878Q90923045-D544CA71-B84F-42FE-AF78-B1DE74CF27C8Q91179614-24EDE489-D0E0-4752-8A9D-94F74A291FE2Q91184902-D25BD581-046B-434B-9DC7-7768B812CDBAQ91504084-A5A7E64D-4EBA-4294-A5A2-F25478B5F313Q92686882-B472538A-F377-4B2E-938A-8C9047294E75Q92918748-03C808E9-4D3A-4DE5-B327-5716B1523EF9
P50
description
natuurkundige
@nl
researcher
@en
հետազոտող
@hy
name
Roy Beck
@nl
Roy Beck-Barkai
@en
Roy Beck-Barkai
@es
רועי בק ברקאי
@he
type
label
Roy Beck
@nl
Roy Beck-Barkai
@en
Roy Beck-Barkai
@es
רועי בק ברקאי
@he
altLabel
Roy Beck
@en
רועי בק
@he
prefLabel
Roy Beck
@nl
Roy Beck-Barkai
@en
Roy Beck-Barkai
@es
רועי בק ברקאי
@he
P101
P1153
35395754800
P21
P31
P496
0000-0003-3121-4530