Small peptide nanofibers as the matrices of molecular hydrogels for mimicking enzymes and enhancing the activity of enzymes.
about
Tumor-Specific Formation of Enzyme-Instructed Supramolecular Self-Assemblies as Cancer TheranosticsSemiconductor nanoparticle-based hydrogels prepared via self-initiated polymerization under sunlight, even visible light.Supramolecular Hydrogelators and Hydrogels: From Soft Matter to Molecular Biomaterials.Rational design of coumarin-based supramolecular hydrogelators for cell imaging.Printable hybrid hydrogel by dual enzymatic polymerization with superactivity.Gel sculpture: moldable, load-bearing and self-healing non-polymeric supramolecular gel derived from a simple organic salt.Glutathione-triggered formation of a Fmoc-protected short peptide-based supramolecular hydrogel.Molecular Self-Assembly Strategy for Generating Catalytic Hybrid Polypeptides.Using experimental and computational energy equilibration to understand hierarchical self-assembly of Fmoc-dipeptide amphiphiles.DEVD-based hydrogelator minimizes cellular apoptosis induction.Protein-induced supramolecular disassembly of amphiphilic polypeptide nanoassemblies.Self-assembly of natural and synthetic drug amphiphiles into discrete supramolecular nanostructures.Artificial enzymes based on supramolecular scaffolds.Design of nanostructures based on aromatic peptide amphiphiles.Multifarious facets of sugar-derived molecular gels: molecular features, mechanisms of self-assembly and emerging applications.Nanospheres of doxorubicin as cross-linkers for a supramolecular hydrogelationA supramolecular hydrogelator of curcumin.Oligomeric hydrogels self-assembled from reduction-controlled condensation.Supramolecular biofunctional materials.Encapsulating [FeFe]-hydrogenase model compounds in peptide hydrogels dramatically modifies stability and photochemistry.β-Galactosidase-instructed formation of molecular nanofibers and a hydrogelNovel anisotropic supramolecular hydrogel with high stability over a wide pH range.Gd(III)-induced Supramolecular Hydrogelation with Enhanced Magnetic Resonance Performance for Enzyme Detection.Self-assembly of cationic multidomain peptide hydrogels: supramolecular nanostructure and rheological properties dictate antimicrobial activity.Self-Assembled 2D Free-Standing Janus Nanosheets with Single-Layer Thickness.Highly stable surface modifications of poly(3-caprolactone) (PCL) films by molecular self-assembly to promote cells adhesion and proliferation.A modular self-assembly approach to functionalised β-sheet peptide hydrogel biomaterials.Sonication-induced coiled fibrous architectures of Boc-L-Phe-L-Lys(Z)-OMe.A fast pH-switchable and self-healing supramolecular hydrogel carrier for guided, local catheter injection in the infarcted myocardium.Enhanced thermal stability and specific activity of Pseudomonas aeruginosa lipoxygenase by fusing with self-assembling amphipathic peptides.Fibrous networks with incorporated macrocycles: a chiral stimuli-responsive supramolecular supergelator and its application to biocatalysis in organic media.HRP-mediated polymerization forms tough nanocomposite hydrogels with high biocatalytic performance.A photo-degradable supramolecular hydrogel for selective delivery of microRNA into 3D-cultured cells.Shape-specific nanostructured protein mimics from de novo designed chimeric peptides.Switchable Hydrolase Based on Reversible Formation of Supramolecular Catalytic Site Using a Self-Assembling Peptide.Enzyme-assisted peptide folding, assembly and anti-cancer properties.Redox-sensitive reversible self-assembly of amino acid-naphthalene diimide conjugates.Hemin-micelles immobilized in alginate hydrogels as artificial enzymes with peroxidase-like activity and substrate selectivity.Lipase catalyzed inclusion of gastrodigenin for the evolution of blue light emitting peptide nanofibers.A platinum(II) terpyridine metallogel with an L-valine-modified alkynyl ligand: interplay of Pt⋅⋅⋅Pt, π-π and hydrogen-bonding interactions.
P2860
Q30365885-C24999DB-A97A-4BC0-938C-67B7B8A53AB6Q30537246-FCBA74DA-2D59-4E7F-9C82-296064C14061Q30781853-05F1DC0D-9534-4FB8-A5E8-70FBD39A5A90Q30865669-CE80DF4A-7451-4601-B2D5-BDB68AC41521Q33814097-25860BF6-AACF-45EC-A2E2-70C98C794C62Q34281280-B03E8B1A-C8D7-45EA-974F-83B6653183F2Q35252652-55D1F1A7-D4D7-4AFB-ADC2-87BA59B1BA38Q35999692-60B33041-DC0C-4CAA-BD5D-47FB71D24067Q36158926-5883447B-6C01-4F15-A6DB-D84925125029Q36845493-C69249E0-C0FE-4EC1-AC7B-E38D4C165061Q37028284-55965F5B-DFF3-4A98-A8C2-E8EAEC6CFCA5Q37638622-B3A70DDC-C3F1-401A-947B-005B19035820Q38042826-B195C141-F4FE-408D-9AB7-A8F6B6692E52Q38246910-0CFCFA6B-A542-4642-9EE5-755AB6178E0DQ38507322-01951C31-1EAA-4635-B699-81BA2419AD6FQ38903553-8B18C406-7232-4A45-B235-F67ABE1F54CBQ38976913-3BA19A8F-CB23-472D-8832-818A8E7DDB35Q39046752-E8BE114B-87EB-4517-AF37-0B04D6EF2556Q39188196-66A52AC1-F981-4E6B-868A-36BAF045F3C3Q39550641-4C6AD6D8-4FE4-43E2-8F63-029B39904B14Q39734206-266DF407-A001-4335-B491-50B7BF6F3BDFQ39734227-48A5F008-D17E-494A-9DE6-745ABC680109Q41196370-94186686-9DFA-4D37-9213-0873FBA4715BQ41546218-9666C44C-5DD7-4B5E-B3EF-1A943F67FD32Q42270147-79163E04-C526-4031-BD6C-B9481C1CA733Q42810008-8E25AB23-979E-4C73-8D28-E03C051C8315Q42816321-F74946B3-B3C1-4CC3-A46B-26AF16FE1985Q44643624-D33BB4C1-7A97-473D-89F7-24A830A5FE83Q44764260-765E7602-6D64-4D9D-A7CD-1F371A992FC2Q45223725-903F84AC-D506-41A1-87E6-CFA0E8C43771Q45752511-FCCC5905-8D7D-4239-8A76-AC4EDDD088A1Q46001094-9B57077C-77A9-4F22-9807-439DD691F595Q46414918-0B7C4DD6-5BED-4EF9-ADAC-7A576D977043Q47205663-FFADF5FA-13E3-4035-A4B3-62F8504EECE2Q47643008-503315ED-A9AF-40E9-B734-36DE5307B474Q47974065-2F5F6B7D-8BF5-4D12-8D54-81BBB5839CD2Q48286576-29316945-DDEE-4A3E-A125-A7C0C3EEE802Q48295847-AC92BD09-8094-46D6-B7F3-C9369EEE237BQ50426593-5D47AD8C-141E-4BEE-9449-57E0569E78A6Q50484764-2F4DD6CD-9171-4A9F-90A6-B763F67E77C9
P2860
Small peptide nanofibers as the matrices of molecular hydrogels for mimicking enzymes and enhancing the activity of enzymes.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 12 July 2010
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@en
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@nl
type
label
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@en
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@nl
prefLabel
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@en
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@nl
P2093
P356
P1476
Small peptide nanofibers as th ...... ncing the activity of enzymes.
@en
P2093
P304
P356
10.1039/B919450A
P577
2010-07-12T00:00:00Z