about
Reversible Morphological Transformation between Polymer Nanocapsules and Thin Films through Dynamic Covalent Self-AssemblyVesicle formed by amphiphilc cucurbit[6]uril: versatile, noncovalent modification of the vesicle surface, and multivalent binding of sugar-decorated vesicles to lectin.Functionalized cucurbiturils and their applications.A bio-inspired swellable microneedle adhesive for mechanical interlocking with tissue.Polymer-based mesh as supports for multi-layered 3D cell culture and assays.A simple modular aptasensor platform utilizing cucurbit[7]uril and a ferrocene derivative as an ultrastable supramolecular linker.Can we beat the biotin-avidin pair?: cucurbit[7]uril-based ultrahigh affinity host-guest complexes and their applications.Genetically engineered mesenchymal stem cell therapy using self-assembling supramolecular hydrogels.Theranostic systems assembled in situ on demand by host-guest chemistry.Supramolecular fishing for plasma membrane proteins using an ultrastable synthetic host-guest binding pair.Carbohydrate wheels: cucurbituril-based carbohydrate clusters.The rate of charge tunneling through self-assembled monolayers is insensitive to many functional group substitutions.Glyco-pseudopolyrotaxanes: carbohydrate wheels threaded on a polymer string and their inhibition of bacterial adhesion.Reduction-sensitive, robust vesicles with a non-covalently modifiable surface as a multifunctional drug-delivery platform.Galactosylated cucurbituril-inclusion polyplex for hepatocyte-targeted gene delivery.Cucurbituril-based nanoparticles: a new efficient vehicle for targeted intracellular delivery of hydrophobic drugs.Ultrastable Artificial Binding Pairs as a Supramolecular Latching System: A Next Generation Chemical Tool for Proteomics.Mono-allyloxylated Cucurbit[7]uril Acts as an Unconventional Amphiphile to Form Light-responsive Vesicles.Self-Healable Supramolecular Hydrogel Formed by Nor-Seco-Cucurbit[10]uril as a Supramolecular Crosslinker.Autophagy Caught in the Act: A Supramolecular FRET Pair Based on an Ultrastable Synthetic Host-Guest Complex Visualizes Autophagosome-Lysosome Fusion.Supramolecular latching system based on ultrastable synthetic binding pairs as versatile tools for protein imaging.Noncovalent immobilization of proteins on a solid surface by cucurbit[7]uril-ferrocenemethylammonium pair, a potential replacement of biotin-avidin pair.Direct Profiling the Post-Translational Modification Codes of a Single Protein Immobilized on a Surface Using Cu-free Click Chemistry.New Encoding Schemes with InfofusesCucurbit[6]uril-based polymer nanocapsules as a non-covalent and modular bioimaging platform for multimodal in vivo imagingSuperacid-Mediated Functionalization of Hydroxylated Cucurbit[n]urilsBio-orthogonal Supramolecular Latching inside Live Animals and Its Application for in Vivo Cancer ImagingSupra-blot: an accurate and reliable assay for detecting target proteins with a synthetic host molecule-enzyme hybridCucurbit[7]uril-conjugated dyes as live cell imaging probes: investigation on their cellular uptake and excretion pathwaysCucurbit[n]uril-based amphiphiles that self-assemble into functional nanomaterials for therapeutics
P50
Q29393761-A79808B8-6F30-4F67-AF81-93CEFE658FB4Q33213740-13FDD86C-1E9C-4AB8-A78E-CED31C098424Q33271030-D128781D-1B51-4974-B24C-D5F002E69B54Q34339645-661FBAD7-E116-4A99-BE17-79C21BB0240CQ37375984-71065E00-63F4-4C13-9241-4CFCDC10B820Q38301643-FB0229A3-1C27-478E-9717-0D4BAEF1E249Q38598659-DAAB0DDD-34CC-4D44-9E2F-9EBB033EFFE5Q38612102-F692EC1A-7DCB-42A2-A82E-EFD2A533F70BQ39501114-4E6D2148-CCAF-4983-8C7C-531EC705090DQ39604110-854E4039-FB19-4BD7-AC76-C3AD8EF665BFQ40088999-538FC5E1-28E2-454F-800F-7E4FFB18B085Q41912281-38E05D5F-2C08-4F7D-815E-28BF9A3C76CAQ42880077-52FA7D02-5753-468E-8EF6-06FF8168B55AQ43011586-967E5EC7-55C6-40A4-89CA-48141C789775Q43189202-9FF8FB78-E5B8-4735-8AA5-6CB7E635F151Q46198819-0D15D1BC-E70B-4489-904C-FEEAC069F6B4Q47636731-90E271CB-94A8-4583-B666-D7BDCB00B125Q47698055-64E6ADA9-D97A-48A6-8A24-527176D0798AQ48366091-1CB02B7B-5BAD-456D-A51D-8A7A56779C21Q48367224-BAE5989F-E6BF-4884-9D14-3C267E07312DQ52716096-36866C7E-6E1C-472F-B607-48E410809CA3Q53575116-C04E6CFE-2043-4D4F-BFB8-19BDA8B030A9Q54960540-146F4ED9-B6A2-4520-A4CF-0C92266174E4Q57705592-E022D75E-B1FD-4F97-9E11-EADE62096B2BQ59197887-DC234AF7-ABB3-4565-9FB2-585A403B693CQ90826043-BFE60E71-3915-47FD-A082-7463041B0DBEQ91109809-9EC42ADF-21D9-4275-9BB6-E2578BCB8687Q92595200-DAD386CC-866C-4569-93B3-1D63D73BA166Q92621665-FAB5758C-3697-406A-B004-00B6F4352413Q92657856-C8B4F161-2C55-4ED4-9768-73EEECFC1CFD
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Kyeng Min Park
@ast
Kyeng Min Park
@en
Kyeng Min Park
@es
Kyeng Min Park
@sl
type
label
Kyeng Min Park
@ast
Kyeng Min Park
@en
Kyeng Min Park
@es
Kyeng Min Park
@sl
prefLabel
Kyeng Min Park
@ast
Kyeng Min Park
@en
Kyeng Min Park
@es
Kyeng Min Park
@sl
P1053
U-1370-2017
P106
P1153
8214979000
P31
P3829
P496
0000-0001-6089-6169
P569
2000-01-01T00:00:00Z