about
Protein recognition using synthetic small-molecular binders toward optical protein sensing in vitro and in live cells.Non-covalent immobilisation of p-toluenesulfonic acid in a porous molecular crystal for size-specific acid-catalysed reactions.Allosteric activation of membrane-bound glutamate receptors using coordination chemistry within living cells.Publisher Correction: An adaptive supramolecular hydrogel comprising self-sorting double nanofibre networks.In situ real-time imaging of self-sorted supramolecular nanofibres.Simultaneous arrangement of up to three different molecules on the pore surface of a metal-macrocycle framework: cooperation and competition.Chiral metal-macrocycle frameworks: supramolecular chirality induction and helicity inversion of the helical macrocyclic structures.Chemogenetic Approach Using Ni(II) Complex-Agonist Conjugates Allows Selective Activation of Class A G-Protein-Coupled ReceptorsRational synthesis of benzimidazole[3]arenes by Cu-catalyzed post-macrocyclization transformationMetal-macrocycle framework (MMF): supramolecular nano-channel surfaces with shape sorting capabilityIn situ X-ray snapshot analysis of transient molecular adsorption in a crystalline channelPalladium- or proton-induced submicro spherical aggregation of macrocyclic amphiphiles in aqueous solutionImaging-Based Study on Control Factors over Self-Sorting of Supramolecular Nanofibers Formed from Peptide- and Lipid-type HydrogelatorspH Nanosensor Using Electronic Spins in DiamondPost-assembly Fabrication of a Functional Multicomponent Supramolecular Hydrogel Based on a Self-Sorting Double NetworkOn-cell coordination chemistry: Chemogenetic activation of membrane-bound glutamate receptors in living cellsThe Power of Confocal Laser Scanning Microscopy in Supramolecular Chemistry: In situ Real-time Imaging of Stimuli-Responsive Multicomponent Supramolecular Hydrogels
P50
Q38389717-84C71A82-F99D-45D0-9210-349F4F05855DQ47306514-4482C65D-FDCF-4D4A-AE0B-22ED7044B1D4Q48339459-E657050D-6EB8-4E35-8DAC-C0B50CFEC317Q48509744-BBBB7777-B41B-44B6-B277-D23DA0D905CAQ51239643-14FE5B43-E9AF-4336-9637-B10B3C9A9527Q53535935-FAD773AE-310D-444F-B0F9-A056E9C956C3Q55192774-0308F9E1-EAE6-46FD-89F3-F0B972F83A2EQ57068927-66BA99FC-913A-4815-A16A-06967AC51385Q58555978-A72024BC-0184-40A1-A3F0-886E4409B000Q82844059-94FDA55E-4FDC-4147-8DE6-83C74C6ECEF6Q85351266-6A0CE189-2F1B-474F-AAFB-5F3EABECA265Q87342983-CA5FD0D9-D2C3-4DD8-A40D-3C141AB0345FQ88615488-D142B5E7-7D8A-4221-ABC9-E01855C2B837Q90186387-34ED3FF3-7BB3-4DAD-9D6A-2F5EC4D51BF2Q92138799-250E2C99-B1CB-4288-B9A4-8B10A7B1FCB9Q92469943-F19D23DA-BB89-4166-A0EF-76535DE16122Q92982112-7A5D76CA-50AA-4268-9FDB-79B783BF30C3
P50
description
researcher ORCID ID = 0000-0001-8112-8169
@en
wetenschapper
@nl
name
Ryou Kubota
@ast
Ryou Kubota
@en
Ryou Kubota
@es
Ryou Kubota
@nl
type
label
Ryou Kubota
@ast
Ryou Kubota
@en
Ryou Kubota
@es
Ryou Kubota
@nl
prefLabel
Ryou Kubota
@ast
Ryou Kubota
@en
Ryou Kubota
@es
Ryou Kubota
@nl
P106
P108
P31
P496
0000-0001-8112-8169