about
One-step large-scale deposition of salt-free DNA origami nanostructures.Metallic Nanostructures Based on DNA Nanoshapes.The enabled state of DNA nanotechnology.DNA Nanostructures as Smart Drug-Delivery Vehicles and Molecular Devices.Virus-encapsulated DNA origami nanostructures for cellular delivery.DNA-Based Enzyme Reactors and Systems.Ionic permeability and mechanical properties of DNA origami nanoplates on solid-state nanoporesDefined-size DNA triple crossover construct for molecular electronics: modification, positioning and conductance properties.Evolution of Structural DNA Nanotechnology.Cellular delivery of enzyme-loaded DNA origami.Protein Coating of DNA Nanostructures for Enhanced Stability and Immunocompatibility.Plasmonic nanostructures through DNA-assisted lithography.Custom-shaped metal nanostructures based on DNA origami silhouettes.Growth of immobilized DNA by polymerase: bridging nanoelectrodes with individual dsDNA molecules.Dielectrophoretic trapping of multilayer DNA origami nanostructures and DNA origami-induced local destruction of silicon dioxide.DNA nanostructure-directed assembly of metal nanoparticle superlattices.Structural stability of DNA origami nanostructures under application-specific conditionsA supramolecular host–guest complex for heparin binding and sensingPackaging DNA Origami into Viral Protein CagesSelf-Assembly of Amphiphilic Janus Dendrimers into Mechanically Robust Supramolecular Hydrogels for Sustained Drug ReleaseCharacterization of the Conductance Mechanisms of DNA Origami by AC Impedance SpectroscopyField-Induced Nanolithography for High-Throughput Pattern TransferDielectrophoretic Trapping of DNA OrigamiA modular DNA origami-based enzyme cascade nanoreactorAutomated design of DNA origamiOn the Stability of DNA Origami Nanostructures in Low-Magnesium BuffersDNA-Assisted Molecular LithographyCationic polymers for DNA origami coating - examining their binding efficiency and tuning the enzymatic reaction ratesAt the Dawn of Applied DNA NanotechnologyDynamic DNA Origami Devices: from Strand-Displacement Reactions to External-Stimuli Responsive SystemsDNA Origami-Mediated Substrate Nanopatterning of Inorganic Structures for Sensing ApplicationsDNA Origami Nanophotonics and Plasmonics at InterfacesDNA origami directed 3D nanoparticle superlattice via electrostatic assemblyIncreasing Complexity in Wireframe DNA NanostructuresHalogen-Bond-Mediated Self-Assembly of Polymer-Resorcinarene ComplexesSerum Albumin-Peptide Conjugates for Simultaneous Heparin Binding and DetectionReal-Time Observation of Superstructure-Dependent DNA Origami Digestion by DNase I Using High-Speed Atomic Force MicroscopySuperstructure-Dependent Loading of DNA Origami Nanostructures with a Groove-Binding DrugNanometrology and super-resolution imaging with DNAReconfigurable DNA Origami Nanocapsule for pH-Controlled Encapsulation and Display of Cargo
P50
Q36192545-724B311E-8658-440C-A870-B3CDF0BA77C8Q37577590-0A57AFC7-B8FA-4D8B-9C50-AB6C00ED3F03Q38097137-DD0B3501-966E-4780-9F5A-4DB1DEE89FA5Q38593539-03B515F8-DC9D-4C84-9480-A1BA228E29AEQ39015663-EDEF6D8F-0B17-4BF1-8F2B-3B34A5446F44Q39196499-6D774F72-1CC9-454D-9B46-A0A87021F948Q39303430-394EBF95-DB44-4B1F-AFBF-E02662CEE7EDQ47374886-E6829FB9-36BA-4F65-8CB3-D9EB7987F3A4Q48176847-B1D2A405-FFED-4312-A80A-BE6BA6EBC822Q48210608-2AC05028-BCF1-4027-93A5-9309AA9D9CE7Q48356793-A7465228-B09D-4D1A-B6C9-337385BD3EDDQ49273443-FD89208C-8951-4F81-A1FB-650F36E9205CQ51490132-84301B1C-6FF3-4EF9-8B20-B2CA03171868Q51546776-C195572D-8BCB-4FA2-80B7-63B359C1BAB0Q53444680-580FE214-2124-4B0E-9D71-F3102C9A6DD7Q55267252-9F1E4371-F210-45D3-9959-B99978E57115Q57300188-E6D4D8D6-5B54-4D46-AA3E-B3304091BDE6Q57377623-99232A4A-B94E-4E71-B77B-8B29F553E21EQ59359771-6EEBBC3B-DD5E-44F9-8691-F04048EA3DAEQ59438848-30ED7E44-90F0-4B8A-AA66-52C61926BAB2Q60155547-E62E6AF3-6121-450C-BFF9-FE197F4E0086Q60155563-F2A5C1AA-3984-4369-9D27-66972B3FB288Q60155583-C0ABC7E2-7EBF-4EF7-BAC9-BE61CE38AB9EQ86546119-4D3B204D-42C3-435A-8DE7-81B964C46585Q88087963-A6A9076C-0C79-4313-A925-BE55BB39E807Q88811992-5E754014-BB1F-414D-8BA7-54D92CFE0932Q89172645-842A94A1-16E6-4E33-873E-1C11A603D122Q89273720-FC7932DE-422E-4EDB-B1DF-74B5C1A28CE7Q89577983-AAC95227-79B4-4DA4-A763-8950E1E296E2Q90419558-623CF43E-BAF3-4751-A8D0-B59422A1D578Q90689267-FA5BEE6C-19A7-464C-A68A-61BB5BB9AA92Q91023189-5EDE6F21-8CF3-470F-95BA-2A6EB0DC18E2Q91922901-C0CB9274-C53E-4900-8A85-3CADA9FE459AQ92120032-FAE72AF1-9F9F-4F2C-9D81-553D4AF4168CQ92184706-B6B7587D-4BC4-4CD8-B933-656026265748Q92347145-EC28D2C8-532B-4917-9918-659BDBE35CCFQ92516187-BD32877F-BF13-4B8F-9B2A-00248A173DB9Q92939004-E6BA1DBE-6BD5-4372-9EF6-265DCCAD4F03Q93107475-B18F6F84-9F3F-4727-BC4E-3A5EC5D23ED2Q93126553-7D9ED041-6CEF-499E-AF86-80BC66F79A21
P50
description
researcher ORCID ID = 0000-0003-2762-1555
@en
wetenschapper
@nl
name
Veikko Linko
@ast
Veikko Linko
@en
Veikko Linko
@es
Veikko Linko
@nl
type
label
Veikko Linko
@ast
Veikko Linko
@en
Veikko Linko
@es
Veikko Linko
@nl
prefLabel
Veikko Linko
@ast
Veikko Linko
@en
Veikko Linko
@es
Veikko Linko
@nl
P108
P31
P496
0000-0003-2762-1555