about
Properties of the force exerted by filopodia and lamellipodia and the involvement of cytoskeletal componentsAdhesion through single peptide aptamers.Microscopy of biological sample through advanced diffractive optics from visible to X-ray wavelength regime.Cross-linking of phospholipid membranes is a conserved property of calcium-sensitive synaptotagminsWave front engineering for microscopy of living cells.Force generation in lamellipodia is a probabilistic process with fast growth and retraction events.Size-dependent cellular uptake of exosomes.Investigation into local cell mechanics by atomic force microscopy mapping and optical tweezer vertical indentation.Re-assembled botulinum neurotoxin inhibits CNS functions without systemic toxicity.Botulinum protease-cleaved SNARE fragments induce cytotoxicity in neuroblastoma cells.Stapling of the botulinum type A protease to growth factors and neuropeptides allows selective targeting of neuroendocrine cellsUse of optical tweezers technology for long-term, focal stimulation of specific subcellular neuronal compartments.Nonparalytic botulinum molecules for the control of pain.Synthetic self-assembling clostridial chimera for modulation of sensory functions.Assembly of protein building blocks using a short synthetic peptideFree jet micromixer to study fast chemical reactions by small angle X-ray scattering.Modular assembly of proteins on nanoparticles.Novel fabrication method for three-dimensional nanostructuring: an application to micro-opticsMie scattering distinguishes the topological charge of an optical vortex: a homage to Gustav MieLocal x-ray structure analysis of optically manipulated biological micro-objectsOptical Tweezers for Sample Fixing in Micro-Diffraction ExperimentsScanning x-ray microdiffraction of optically manipulated liposomesCombined laser trapping and small-angle x-ray scattering experiment for the study of liposome colloidal microparticlesCow Milk and Intestinal Epithelial Cell-derived Extracellular Vesicles as Systems for Enhancing Oral Drug DeliveryA thermo-responsive, self-assembling biointerface for on demand release of surface-immobilised proteinsBiocleaning of starch glues from textiles by means of α-amylase-based treatments
P50
Q27302614-C1CB1F43-190A-44E3-9B3A-4BEE31B916D7Q30437104-117CB208-68E4-481F-8039-4604AB4B7EE0Q33210565-7B810FC8-6069-49B1-8DA1-054D875AE579Q33338314-D95BDD76-1CDA-4892-AB08-CC57E1808C3CQ33459911-0EEE7CAC-306C-47A1-BEE7-3F66ED9CDDFFQ33767660-46BBCD56-4F0A-4676-8D25-7414D6C0E1E2Q38725426-C025CFBD-EDE7-4097-B6A5-A1DF2B0ED54FQ38810573-C7E390C0-C0CA-4F75-931D-C69E6AD143A3Q38843144-C7382650-BE01-4575-864B-197A1C80238CQ39039170-FD0AFC88-EF01-45D1-B3BD-BA4C6928B891Q39157207-D02E1C2D-BF8A-4198-93D8-26C381C5904DQ39570805-724360EB-C494-44EE-888D-A204AB4EFC9FQ40113769-9213B4EB-E937-446D-BB1E-EFE9999F62E8Q41876523-77AEB6D0-F1E0-48FB-920A-01493D51C577Q42574076-FD363697-106B-46B8-ACD8-9E8D565CEF80Q45944990-7C1B6E94-62BA-45A1-A4F8-F8F903587719Q52584537-E04FC1A8-0755-4AA5-9AF9-C92735EBD1FDQ56925892-FFCDBAEE-62A2-45D0-889B-E91037F1B1D5Q57515452-51011837-9F86-4B32-844C-438CAE88CAE3Q61845000-84DA1CEF-FA4C-4BE7-A90B-1D5B71024020Q61845012-5899829D-6B4A-487E-9674-71F4B155F108Q61845015-735F6900-BC57-453D-85A8-D1A1FA22D7E9Q61845022-B2FED5C3-92D4-4415-AD57-481EE263B52AQ90114399-7B1902E4-40A4-4514-A29D-6407A9B02875Q91623934-F27EAB07-4E18-4D2D-AA6A-B050F3194700Q93168987-6FA2F663-176F-4B5D-AECB-B75FFC840205
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Enrico Ferrari
@ast
Enrico Ferrari
@en
Enrico Ferrari
@es
Enrico Ferrari
@nl
Enrico Ferrari
@sl
type
label
Enrico Ferrari
@ast
Enrico Ferrari
@en
Enrico Ferrari
@es
Enrico Ferrari
@nl
Enrico Ferrari
@sl
prefLabel
Enrico Ferrari
@ast
Enrico Ferrari
@en
Enrico Ferrari
@es
Enrico Ferrari
@nl
Enrico Ferrari
@sl
P1053
A-9676-2011
P106
P1153
34769896200
P21
P31
P3829
P496
0000-0002-9102-7422