about
G-protein coupled receptor array technologies: site directed immobilisation of liposomes containing the H1-histamine or M2-muscarinic receptors.Multilayers of hydrogels loaded with microparticles: a fast and simple approach for microarray manufacturing.Osteoblast-derived WNT16 represses osteoclastogenesis and prevents cortical bone fragility fracturesNanoscale labels: nanoparticles and liposomes in the development of high-performance biosensors.Mucosal Vaccine Development Based on Liposome Technology.The Matrix protein M1 from influenza C virus induces tubular membrane invaginations in an in vitro cell membrane model.Liposome and lipid bilayer arrays towards biosensing applications.Mucin-like Region of Herpes Simplex Virus Type 1 Attachment Protein Glycoprotein C (gC) Modulates the Virus-Glycosaminoglycan InteractionHisto-Blood Group Antigen Presentation Is Critical for Binding of Norovirus VLP to Glycosphingolipids in Model Membranes.Methods for the physical characterization and quantification of extracellular vesicles in biological samples.Liposomes and lipid bilayers in biosensors.Binding Kinetics and Lateral Mobility of HSV-1 on End-Grafted Sulfated Glycosaminoglycans.Interaction of Virus-Like Particles with Vesicles Containing Glycolipids: Kinetics of Detachment.Equilibrium-fluctuation-analysis of single liposome binding events reveals how cholesterol and Ca2+ modulate glycosphingolipid trans-interactionsNorovirus GII.4 virus-like particles recognize galactosylceramides in domains of planar supported lipid bilayers.Parvovirus B19 VLP recognizes globoside in supported lipid bilayers.A virus biosensor with single virus-particle sensitivity based on fluorescent vesicle labels and equilibrium fluctuation analysis.Interaction of virions with membrane glycolipids.Determination of exosome concentration in solution using surface plasmon resonance spectroscopy.Issues of ligand accessibility and mobility in initial cell attachment.Dual-Wavelength Surface Plasmon Resonance for Determining the Size and Concentration of Sub-Populations of Extracellular Vesicles.A nano flow cytometer for single lipid vesicle analysis.Evanescent Light-Scattering Microscopy for Label-Free Interfacial Imaging: From Single Sub-100 nm Vesicles to Live Cells.A cell membrane derived platform to study virus binding kinetics and diffusion with single particle sensitivity.Interactions between Titanium Dioxide and Phosphatidyl Serine-Containing Liposomes: Formation and Patterning of Supported Phospholipid Bilayers on the Surface of a Medically Relevant MaterialLocation-specific nanoplasmonic sensing of biomolecular binding to lipid membranes with negative curvatureInteraction of single viruslike particles with vesicles containing glycosphingolipidsMicroarrays made easy: biofunctionalized hydrogel channels for rapid protein microarray productionZirconium ion mediated formation of liposome multilayersEffective Refractive Index and Lipid Content of Extracellular Vesicles Revealed Using Optical Waveguide Scattering and Fluorescence MicroscopyRegulatory Mechanisms of the Mucin-Like Region on Herpes Simplex Virus during Cellular AttachmentLipid vesicle composition influences the incorporation and fluorescence properties of the lipophilic sulphonated carbocyanine dye SP-DiOBacteria-Based Production of Thiol-Clickable, Genetically Encoded Lipid NanovesiclesGel Phase 1,2-Distearoyl-sn-glycero-3-phosphocholine-Based Liposomes Are Superior to Fluid Phase Liposomes at Augmenting Both Antigen Presentation on Major Histocompatibility Complex Class II and Costimulatory Molecule Display by Dendritic Cells in
P50
Q33425346-E7D5040C-4E32-4727-AAED-1EF525A2EEEEQ33525597-5A78912C-AA32-42DA-B842-4209FBB4CFE4Q35360217-BB4D7A42-E226-4974-9160-DD1805843D02Q37510932-11D6CC67-0917-40C0-9175-EB8C15833B39Q37581129-5B53EA28-1767-4650-9CE5-77955202948CQ37604915-18EEEE1D-B4A7-425E-922B-EE5A59AA3C78Q37798228-A465B9EE-1F9D-48BD-A288-EFF1C6838845Q38854789-6D232111-E254-4E1A-A7F9-2F72AB4D4B34Q38907335-48B1B6BA-2691-447E-AA1B-388258AE621DQ38919870-E6D1A3A1-FFE3-4754-BC56-5FCCF18AFCF2Q39364859-20217949-F8BA-470C-AFB0-B321E8EEB6D7Q40126963-FCA5E597-6803-416C-A6E0-501A1650ABD4Q41060566-650B0437-480F-4FA3-9EEA-0192429CC1B6Q41157069-4CF648C3-247F-4347-85F3-C7CD0247D65CQ41892006-8EB50566-535C-4884-A447-4EE2971B8A95Q42212619-5E722BE0-C145-4F9A-9AD1-7DECE5242705Q42220434-93089F69-9BC0-411C-9AD0-C9AA885F3C5AQ44814559-3C08C3CA-3D99-4A36-A566-48FC094F1839Q45865297-AE615968-5264-455F-AA7B-CBE9B9FB79A1Q46964534-6A305071-C00C-4468-8C57-10FA9486E926Q47272819-9684BFBD-93DD-4C5C-A2AE-4514954A95BCQ48304921-4A376A79-A286-4FB2-A037-1ECC8DF37EFEQ51478124-82CFC296-5DBC-48EC-BDE1-1DAC87617B06Q52567547-022FE81A-0567-4794-B227-B38657FB440CQ58029731-B517DE30-03D8-4BCB-9FF9-725271250805Q60026470-47C5D34A-4D30-44A2-9A58-DE4DC018EE3DQ82632845-B2D0A625-B457-4BDE-8946-34E988DD8AB7Q82803800-CAF389A8-BD3F-4AAA-822D-EDF13BEC6C02Q84314496-EE500667-9BED-47AD-A70C-006B664CADB6Q89164183-8D2C079A-1F9C-4713-9420-F54A2D2C8A11Q91419792-AFCF939A-484A-439A-AE7A-5BF68B6434DDQ91879607-81DEC204-F8F1-4DF4-B749-1CB6BFCB9BDEQ92752091-696DCD27-F367-4862-9749-DE7D0BF09FC8Q93197354-724184B0-8EE1-458F-9FF5-6100EE10A9ED
P50
description
hulumtuese
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Marta Bally
@ast
Marta Bally
@en
Marta Bally
@es
Marta Bally
@nl
type
label
Marta Bally
@ast
Marta Bally
@en
Marta Bally
@es
Marta Bally
@nl
prefLabel
Marta Bally
@ast
Marta Bally
@en
Marta Bally
@es
Marta Bally
@nl
P108
P106
P21
P31
P496
0000-0002-5865-8302