Expanding the scope of gels – combining polymers with low-molecular-weight gelators to yield modified self-assembling smart materials with high-tech applications
about
Printable hybrid hydrogel by dual enzymatic polymerization with superactivity.Preparation of supramolecular hydrogel-enzyme hybrids exhibiting biomolecule-responsive gel degradation.1,3:2,4-Dibenzylidene-D-sorbitol (DBS) and its derivatives--efficient, versatile and industrially-relevant low-molecular-weight gelators with over 100 years of history and a bright future.Applying low-molecular weight supramolecular gelators in an environmental setting - self-assembled gels as smart materials for pollutant removal.Peptide based hydrogels for cancer drug release: modulation of stiffness, drug release and proteolytic stability of hydrogels by incorporating d-amino acid residue(s).Gels with sense: supramolecular materials that respond to heat, light and sound.Supramolecular materials.Spatially-resolved soft materials for controlled release - hybrid hydrogels combining a robust photo-activated polymer gel with an interactive supramolecular gel.A dipeptide-based superhydrogel: Removal of toxic dyes and heavy metal ions from waste water.Multi-component hybrid hydrogels - understanding the extent of orthogonal assembly and its impact on controlled release.An adaptive supramolecular hydrogel comprising self-sorting double nanofibre networks.Crosslinker-Induced Effects on the Gelation Pathway of a Low Molecular Weight Hydrogel.Tunable hygromorphism: structural implications of low molecular weight gels and electrospun nanofibers in bilayer composites.Polymerization of low molecular weight hydrogelators to form electrochromic polymers.Metal 'turn-off', anion 'turn-on' gelation cascade in pyridinylmethyl ureas.Morphology transition in helical tubules of a supramolecular gel driven by metal ions.G-Quartet hydrogels for effective cell growth applications.Facile Construction of Structurally Defined Porous Membranes from Supramolecular Hexakistriphenylamine Metallacycles through Electropolymerization.Scaleable two-component gelator from phthalic acid derivatives and primary alkyl amines: acid-base interaction in the cooperative assembly.Self-Assembled Fibers Containing Stable Organic Radical Moieties: Alignment and Magnetic Properties in Liquid Crystals.First report of charge-transfer induced heat-set hydrogel. Structural insights and remarkable properties.Topochemical polymerization of dumbbell-shaped diacetylene monomers: relationship between chemical structure, molecular packing structure, and gelation property.A G4·K(+) hydrogel that self-destructs.Selective Extraction and In Situ Reduction of Precious Metal Salts from Model Waste To Generate Hybrid Gels with Embedded Electrocatalytic Nanoparticles.Tuning Syneresis Properties of Kappa-Carrageenan Hydrogel by C2-Symmetric Benzene-Based Supramolecular GelatorsHybrid hydrogels assembled from phenylalanine derivatives and agarose with enhanced mechanical strengthSelf-assembled sorbitol-derived supramolecular hydrogels for the controlled encapsulation and release of active pharmaceutical ingredientsInvestigating hydrogel formation using variable-temperature scanning probe microscopySelf-assembled hybrid hydrogels based on an amphipathic low molecular weight peptide derivative and a water-soluble poly(para-phenylene vinylene)
P2860
Q33814097-9486D33F-2C94-4B4E-B06A-EC7EC9535557Q36112722-78631916-927F-4B20-91CB-6C4FDB730C0BQ38504478-BE26AA49-0221-48C2-B2C1-79B0913ACAE1Q38848399-610F73EE-6F85-4315-B3CA-AA8D2EE07A9CQ38893813-85F322F1-F465-4F52-922F-C53121E43580Q38973655-3B50640B-E64D-4A1E-892E-BE3AAD6C0938Q39263322-6918E767-F148-4BCC-BC47-5B6A5E84A3C4Q42707742-E6F927F3-03DC-46F6-908D-0B468A7C245EQ46781042-28CBA7DD-51D4-4B05-A90D-F5ED4AF83A11Q47126442-03996F07-D0B0-454C-9351-D0680E37162AQ47192827-B349A64D-D5A3-4531-A8EC-08DD01C1BCB4Q47240789-9E9ED840-F13B-4813-9F59-61052AFD5488Q47289588-D2F3EECA-620E-42B6-8F83-FACFA58D9734Q47384189-4EF9B29F-4B3C-4D5E-9F40-A2569EA156DEQ48310443-505C90BB-99FC-4D5F-958C-EC3C64AE7F55Q48347426-CAE61720-3834-4222-B112-00A72EC2A06DQ50050048-3544DE1E-5B6A-4677-BD96-1623601EA4EAQ50235164-D319803A-2A3C-456C-B00A-BA41DEBAEE82Q50865427-7D3A712E-FBE9-4AA2-A581-38C08B257CB5Q51319112-CC7BE0F2-6148-4DAD-8003-EE7F1DBDF355Q53091502-6B0080B5-DD0E-4C79-A90A-459D54DE7C5AQ53132715-B7824A4D-1B52-4DE7-B3E6-D8899C1A375DQ53167068-521EE509-0ECE-4605-94FB-98D874644CCDQ53657352-CC8749CD-4071-4D62-BF84-3DE09ECCA4DCQ57343094-0F48F578-F917-4F65-B1C1-0F25D9134F75Q57355977-E54B0D43-5CFD-491B-93A9-B2DC690A5B9AQ58324574-F73571D1-8089-466E-B148-DA45C34AC9E2Q58450642-0DBFB7ED-30BF-4224-9A3F-4A45A1C6D4DFQ59260497-78DC0E90-BAD3-49EB-9FFA-E653CBF5272D
P2860
Expanding the scope of gels – combining polymers with low-molecular-weight gelators to yield modified self-assembling smart materials with high-tech applications
description
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2015
@uk
name
Expanding the scope of gels – ...... ls with high-tech applications
@en
Expanding the scope of gels – ...... ls with high-tech applications
@nl
type
label
Expanding the scope of gels – ...... ls with high-tech applications
@en
Expanding the scope of gels – ...... ls with high-tech applications
@nl
prefLabel
Expanding the scope of gels – ...... ls with high-tech applications
@en
Expanding the scope of gels – ...... ls with high-tech applications
@nl
P2860
P356
P1433
P1476
Expanding the scope of gels – ...... ls with high-tech applications
@en
P2093
Daniel J. Cornwell
P2860
P304
P356
10.1039/C4MH00245H
P407
P577
2015-01-01T00:00:00Z