about
Protein-polymer therapeutics: a macromolecular perspective.A disulfide intercalator toolbox for the site-directed modification of polypeptides.pH responsive Janus-like supramolecular fusion proteins for functional protein delivery.Efficient delivery of p53 and cytochrome c by supramolecular assembly of a dendritic multi-domain delivery system.Dendronized albumin core-shell transporters with high drug loading capacity.Programming supramolecular biohybrids as precision therapeutics.Precision biopolymers from protein precursors for biomedical applications.A core-shell albumin copolymer nanotransporter for high capacity loading and two-step release of doxorubicin with enhanced anti-leukemia activity.Heterocyclic thionates as a new class of bridging ligands in oxo-centered triangular cyclopentadienylchromium(III) complexes.Coupling of CpCr(CO)3 and heterocyclic dithiadiazolyl radicals. synthetic, x-ray diffraction, dynamic NMR, EPR, CV, and DFT studies.Tuning polarity of polyphenylene dendrimers by patched surface amphiphilicity--precise control over size, shape, and polarity.Synthetic and X-ray structural and reactivity studies of Cp*RuIV complexes containing bidentate dithiocarbonate, xanthate, carbonate, and phosphinate ligands (Cp* = eta5-C5Me5).A Supramolecular Approach toward Bioinspired PAMAM-Dendronized Fusion Toxins.Constructing hybrid protein zymogens through protective dendritic assembly.Cross-conjugation of DNA, proteins and peptides via a pH switchEngineering Proteins at Interfaces: From Complementary Characterization to Material Surfaces with Designed FunctionsWater-soluble allyl sulfones for dual site-specific labelling of proteins and cyclic peptidesProgrammable protein–DNA hybrid hydrogels for the immobilization and release of functional proteinspH-Responsive Quantum Dots via an Albumin Polymer Surface CoatingAntimicrobial and Anti-Biofilm Activities of Surface Engineered Polycationic Albumin Nanoparticles with Reduced Hemolytic ActivityBoosting Antitumor Drug Efficacy with Chemically Engineered Multidomain ProteinsFunctional protein nanostructures: a chemical toolboxProgramming Bioactive Architectures with Cyclic Peptide AmphiphilesCoordination complexes of thiazyl rings — Synthesis, structure, and density functional theory (DFT) computational analysis of CpCr(CO)x (x = 2, 3) complexes of fluorinated and nonfluorinated 1λ3-1,2,4,6-thiatriazinyls with differing Cr–S bond orMacromol. Rapid Commun. 2/2014Mixed-Sandwich (Cp*/(HMB))Ru Complexes Containing Bis(methimazolyl)(pyrazolyl)borate (Cp* = η5-C5Me5, HMB = η6-C6Me6)Mixed-Sandwich Cp*Cr Complexes Containing Poly(methimazolyl)borates (Cp* = C5Me5): Syntheses and Structural and Electrochemical StudiesA tert-butyl/cyano substituted (1,2,3,5-dithiadiazolyl)benzene and η2 π complexes with CpCr(CO)2HMB and Cp* ruthenium(II) complexes containing bis- and tris-(mercaptomethimazolyl)borate ligands: Synthetic, X-ray structural and electrochemical studies (HMB=η6-C6Me6, Cp*=η5-C5Me5)Highly Oxidized Ruthenium Organometallic Compounds. The Synthesis and One-Electron Electrochemical Oxidation of [Cp*RuIVCl2(S2CR)] (Cp* = η5-C5Me5, R = NMe2, NEt2, OiPr)η1and η2complexes of λ3-1,2,4,6-thiatriazinyls with CpCr(CO)xReactivity of [CpCr(CO)3]2 towards thione (CS) moieties in some sulfur-containing substratesRedox-Dependent Isomerization of Organometallic RuII/RuIIICompounds Containing the Hydrotris(methimazolyl)borate Ligand: An Electrochemical Square Scheme MechanismComparative reactivity studies of dppf-containing CpRuII and (C6Me6)RuII complexes towards different donor ligands (dppf=1,1′-bis(diphenylphosphino)ferrocene)Patchy Amphiphilic Dendrimers Bind Adenovirus and Control Its Host Interactions and in Vivo DistributionSomatostatin receptor mediated targeting of acute myeloid leukemia by photodynamic metal complexes for light induced apoptosisSite-selective protein modification via disulfide rebridging for fast tetrazine/trans-cyclooctene bioconjugation
P50
Q38555997-AD4F4EAB-FF2A-42A6-AF5D-BE247BFBB609Q38943671-44EAB52C-4B25-4424-A7EC-F3F61D1B76FDQ39071241-633B68BC-BFF7-4D4B-BD53-78476D65DB2FQ39154600-937AB65B-A62B-493E-A6BE-53FD0D4C67DAQ39232641-5EE69F45-B20C-4A04-B625-C3A831D51F92Q43493008-8BE336E6-1B9B-451F-B519-1C5E7E4F6326Q43733735-D641688D-56D6-494D-93BA-60FA2B26F45AQ46216740-1BD611AE-F329-4328-9D56-C7467582AE89Q46602844-F013A422-6EE5-4BF4-8472-D093E215291FQ46831144-0E227423-407A-40C5-97DB-3A576ADC7CDEQ47198009-67CBBED5-AC9C-44A4-B93C-A376234BEBBFQ50705843-9CE2F010-74CA-4E46-82B5-89889FAD5295Q52886432-DF65DA91-35F5-4FAB-AA49-95F7BBAEDDDFQ54388483-DC36931C-B862-498C-AB77-B481AC978863Q57729196-25F23F02-911A-4DB4-ADD5-938804E09948Q57947018-19F71351-9CAB-4E68-A9EC-7DA86B400FEBQ58202898-D771F961-E4BC-4544-8CB7-5128646203CEQ58202918-A8529388-34EC-4759-8A81-F0B60EEC3CC6Q58202936-2E126EF6-5416-42B5-AE86-C2C4E5AEECD1Q62117792-31A39D5A-2EE1-480F-8C89-4F99D41991C0Q62117793-26F5866B-B58F-4080-AC0F-8FBC61A738C6Q62117794-A596379B-1EBD-4635-9CBF-31FFA4551347Q62117796-B4CF55CE-0522-440B-8698-573DDC02BADDQ62117797-036F5F4D-248F-4996-AC44-35F2A63F1658Q62117799-3572B894-3E3A-4126-84BD-4AA0CB499E36Q62117801-DE3D2B7C-978B-436C-BAC2-6B6911002E91Q62117802-3813C05C-254A-4919-BDEC-ECED13491E1EQ62117803-AEA2A627-79DA-42BD-A2AD-C6F518D9E9EAQ62117804-EAB82E9C-FF22-40B7-8B13-AE68DE94F54CQ62117805-48C1B3C2-72F2-48E7-A3EE-867FDDDC0CDCQ62117806-07EEB7E6-3440-4ABD-8A99-97FFFD250BEFQ62117807-73EE190E-572A-405C-A1DB-03D886C6EFFBQ62117808-1EBC2722-3EDC-4A91-BCFB-303F5248E80EQ62117810-0A4BF3AE-5A80-47ED-ABAC-7EF9AA6C990EQ92020016-CA16EF9C-4D6B-4D6C-A414-BFFD10F2ACD1Q92668893-5B53F7E4-6364-421A-808A-5AEE2FED0158Q92870190-6FD7C8AE-D58D-421B-ABE9-90A865AB0A7B
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Seah Ling Kuan
@ast
Seah Ling Kuan
@en
Seah Ling Kuan
@es
Seah Ling Kuan
@nl
type
label
Seah Ling Kuan
@ast
Seah Ling Kuan
@en
Seah Ling Kuan
@es
Seah Ling Kuan
@nl
prefLabel
Seah Ling Kuan
@ast
Seah Ling Kuan
@en
Seah Ling Kuan
@es
Seah Ling Kuan
@nl
P106
P31
P496
0000-0003-3945-4491