about
Anion-π catalysis: bicyclic products with four contiguous stereogenic centers from otherwise elusive diastereospecific domino reactions on π-acidic surfaces.Efficient Delivery of Quantum Dots into the Cytosol of Cells Using Cell-Penetrating Poly(disulfide)s.Anion-π Catalysis of Diels-Alder Reactions.Strained Cyclic Disulfides Enable Cellular Uptake by Reacting with the Transferrin Receptor.Catalysis with Chalcogen Bonds.Strain-Promoted Thiol-Mediated Cellular Uptake of Giant Substrates: Liposomes and Polymersomes.Electric-Field-Assisted Anion-π Catalysis.Headgroup engineering in mechanosensitive membrane probes.Dipolar Photosystems: Engineering Oriented Push-Pull Components into Double- and Triple-Channel Surface Architectures.Asymmetric Anion-π Catalysis on Perylenediimides.Anion-π Catalysts with Axial Chirality.Anion-π Catalysis on Fullerenes.Catalysis with chalcogen bonds: neutral benzodiselenazole scaffolds with high-precision selenium donors of variable strength.Catalysis with Pnictogen, Chalcogen, and Halogen Bonds.Diselenolane-mediated cellular uptake.Conjugated Polyimine Dynamers as Phase-Sensitive Membrane ProbesWhite-Fluorescent Dual-Emission Mechanosensitive Membrane Probes that Function by Bending Rather than TwistingPrimary Anion−π Catalysis and AutocatalysisStreptavidin interfacing as a general strategy to localize fluorescent membrane tension probes in cells.Detecting order and lateral pressure at biomimetic interfaces using a mechanosensitive second-harmonic-generation probeRemote Control of Anion-π Catalysis on Fullerene-Centered Catalytic TriadsPrimary Anion-π Catalysis of Epoxide-Opening Ether Cyclization into Rings of Different Sizes: Access to New ReactivityCell-Penetrating Streptavidin: A General Tool for Bifunctional Delivery with Spatiotemporal Control, Mediated by Transport Systems Such as Adaptive Benzopolysulfane NetworksA Chalcogen-Bonding Cascade Switch for Planarizable Push-Pull ProbesAnion-π Catalysis on Carbon NanotubesPolyether Natural Product Inspired Cascade Cyclizations: Autocatalysis on π-Acidic Aromatic SurfacesProbing for Thiol-Mediated Uptake into BacteriaFluorescent Flipper Probes: Comprehensive Twist CoverageAnion Transport with Pnictogen Bonds in Direct Comparison with Chalcogen and Halogen BondsThe Emergence of Anion-π CatalysisMechanosensitive Fluorescent Probes to Image Membrane Tension in Mitochondria, Endoplasmic Reticulum, and LysosomesDiselenolane-Mediated Cellular Uptake: Efficient Cytosolic Delivery of Probes, Peptides, Proteins, Artificial Metalloenzymes and Protein-Coated Quantum DotsPeptide Stapling with Anion-π CatalystsCell-Penetrating Dynamic-Covalent Benzopolysulfane NetworksDithienothiophenes at Work: Access to Mechanosensitive Fluorescent Probes, Chalcogen-Bonding Catalysis, and BeyondSingle-Molecule Kinetics of Growth and Degradation of Cell-Penetrating Poly(disulfide)sPlanarizable Push-Pull Probes: Overtwisted Flipper MechanophoresBlack Lipid Membranes: Challenges in Simultaneous Quantitative Characterization by Electrophysiology and Fluorescence Microscopy
P50
Q33703228-41F66E7F-EC7A-49E3-88A7-7F3C04732727Q41362676-DA8A2214-1008-4E1A-9903-B4D253BC5893Q48104670-F8D6286D-0664-42C9-9745-04AB8B5EC027Q48129919-4F8574A7-460C-45B4-956E-C94BCE1494A6Q48146687-62A4AD96-580C-44BA-9B4D-CC7E37EF3AF7Q48162635-91D51A78-21E6-4476-866A-AA8437A4C8B2Q48177576-F87260B9-DF66-4423-9702-C0AF61DF50A7Q48188548-F83CBC82-76D4-488E-85F7-593AD6A3408CQ48228060-7EF330A7-CB26-4ACB-B413-B9509133A200Q48248383-2FA77F36-F870-4AE3-BBE2-45C443B13966Q48259999-5FF08B8C-1CA3-495C-B8E3-6FB484196F64Q48352820-D237EAB4-7C44-432C-86E2-0830266D2F4DQ52641516-82301897-3BBD-4B13-A575-0B93EED886C3Q55026797-B6F364A8-24AD-4646-A891-A9F484FB2938Q55101649-5E04A2FB-F8E1-4831-8B93-057D899D3ACAQ57346342-AF9791D5-16DE-46C5-99E2-B84B76FB4468Q57902943-68055656-9567-4877-BEF5-5913D38CDF14Q64034059-0811046B-A0C7-4BC4-9DE8-400A25C74763Q64924805-1DAC9BA1-8802-44AB-B923-0C1F559C0A48Q88127763-917457E3-EDB3-434A-85A9-C15560D492FCQ88881148-7921FF5E-454F-4E12-B8ED-BAB458A0C398Q89800790-B17826BF-DA09-40E6-9BED-A5EA7EAE27E5Q89935026-AC7DD909-0911-4B4A-9780-D84B941701CBQ90189522-721FE9FD-F5F6-4C5F-BDC0-839C6A9DF542Q90253713-F7A32378-63D5-4170-B864-0F80C0947F80Q90386085-4FDBE402-CE39-4FE4-BC63-B9180DA06CA9Q90650642-66D7F49C-FE1F-425B-B96F-2EA75EDA96A1Q90869028-2D1FA162-B6B5-4A28-AB11-E64F02BA36B8Q90933811-B1A151E7-C0E5-4EA6-AFEA-14B3D877F1C4Q91315559-5F7B16A4-646C-4611-A502-9CFB95EA0BB1Q91462542-2E608FD3-DE87-48A3-B777-D5FF87D0B84BQ91994711-D0D41C99-8F3E-4A7B-85E9-C8E98FC96CC7Q92080462-FC51D2F3-E958-4AE0-91D5-1AF4FFA35858Q92554447-C2CA3701-CDA2-41FC-A87E-54828BBB02CCQ92634146-BE3F8FD3-D447-44B7-8221-E84011B2B8EBQ92736015-F144E1F7-2546-44AE-82F4-4DEABF4DA035Q92800271-8E2943A4-5256-451E-9579-97B37C880D87Q93059093-BD575CC2-2105-499E-82D0-B2CA351BDA76
P50
description
researcher (ORCID 0000-0002-8537-8349)
@en
wetenschapper
@nl
name
Stefan Matile
@en
Stefan Matile
@nl
type
label
Stefan Matile
@en
Stefan Matile
@nl
prefLabel
Stefan Matile
@en
Stefan Matile
@nl
P31
P496
0000-0002-8537-8349