The importance of the self-assembly process to control mechanical properties of low molecular weight hydrogels.
about
β sheets not required: combined experimental and computational studies of self-assembly and gelation of the ester-containing analogue of an Fmoc-dipeptide hydrogelator.Seamless metallic coating and surface adhesion of self-assembled bioinspired nanostructures based on di-(3,4-dihydroxy-L-phenylalanine) peptide motif.Rheology of peptide- and protein-based physical hydrogels: are everyday measurements just scratching the surface?Structural determinants in a library of low molecular weight gelators.Preparation of supramolecular hydrogel-enzyme hybrids exhibiting biomolecule-responsive gel degradation.Synthesis of Fluorescent Gelators and Direct Observation of Gelation with a Fluorescence Microscope.Gelation Landscape Engineering Using a Multi-Reaction Supramolecular Hydrogelator SystemCation Tuning toward the Inference of the Gelation Behavior of Supramolecular Gels.Insights into low molecular mass organic gelators: a focus on drug delivery and tissue engineering applications.Design of nanostructures based on aromatic peptide amphiphiles.Multifarious facets of sugar-derived molecular gels: molecular features, mechanisms of self-assembly and emerging applications.A naphthalene-containing amino acid enables hydrogelation of a conjugate of nucleobase-saccharide-amino acids.Adaptive soft molecular self-assemblies.Photoresponsive gelators.Structure-mechanical property correlations of hydrogel forming β-sheet peptides.Peptide based hydrogels for cancer drug release: modulation of stiffness, drug release and proteolytic stability of hydrogels by incorporating d-amino acid residue(s).Peptide self-assembly: thermodynamics and kinetics.Hierarchical construction of a mechanically stable peptide-graphene oxide hybrid hydrogel for drug delivery and pulsatile triggered release in vivo.A supramolecular hydrogelator of curcumin.Self-assembly of biopolymers - recent progress and future prospects.Ultrashort self-assembling Fmoc-peptide gelators for anti-infective biomaterial applications.Luminescent supramolecular hydrogels from a tripeptide and nitrogen-doped carbon nanodots.Using molecular rotors to probe gelation.Magnetically aligned supramolecular hydrogels.Gd(III)-induced Supramolecular Hydrogelation with Enhanced Magnetic Resonance Performance for Enzyme Detection.Structure and growth behavior of centimeter-sized helical oleate assemblies formed with assistance of medium-length carboxylic acids.Opening a Can of Worm(-like Micelle)s: The Effect of Temperature of Solutions of Functionalized Dipeptides.Mixing biomimetic heterodimers of nucleopeptides to generate biocompatible and biostable supramolecular hydrogels.Self-sorted photoconductive xerogels.Assessing the Potential of Folded Globular Polyproteins As Hydrogel Building BlocksBiocatalytically triggered co-assembly of two-component core/shell nanofibers.Primary ammonium monocarboxylate synthon in designing supramolecular gels: a new series of chiral low-molecular-weight gelators derived from simple organic salts that are capable of generating and stabilizing gold nanoparticles.Enzyme-controllable delivery of nitric oxide from a molecular hydrogel.Phenylalanine-containing cyclic dipeptides--the lowest molecular weight hydrogelators based on unmodified proteinogenic amino acids.A quest for supramolecular gelators: silver(I) complexes with quinoline-urea derivatives.Dipeptide concave nanospheres based on interfacially controlled self-assembly: from crescent to solid.A dipeptide-based superhydrogel: Removal of toxic dyes and heavy metal ions from waste water.Tailor-made design of J- or H-aggregated naphthalenediimide-based gels and remarkable fluorescence turn on/off behaviour depending on solvents.Optimising low molecular weight hydrogels for automated 3D printing.Crosslinker-Induced Effects on the Gelation Pathway of a Low Molecular Weight Hydrogel.
P2860
Q33609184-DD57AF1A-6C79-4C6E-8259-92EBC1EC62FAQ33939465-B1E8FE55-0755-4734-9165-710ACD4E7C30Q35285779-9110CBC5-A650-4CEB-BF70-59C4AD60EFD2Q35538872-BD150409-967F-41D6-924E-AC72B1F8C2FDQ36112722-FFA0AF0E-7B8F-44F0-9172-E3BC7ADF3364Q36159131-4C8B7FAD-9B1C-43AA-84B5-22C5F209AA2CQ36305724-D9FC68EE-391C-4706-B7D2-AA0BE5DDEB41Q36860535-CD910AF9-3221-4049-9E94-5C7A941DFE61Q38197907-1A252103-8B2D-4BAC-8B25-80E97E8D4174Q38246910-CD6FC359-139E-4042-BD12-6FC183D89BF2Q38507322-56E2A41D-DF90-4942-A03E-91C151137E5BQ38607789-DB5E9494-D4CF-4C41-8ED1-C86B28E2D73CQ38618305-F5902DE4-59BB-4954-A60B-3BE99DEE144DQ38843818-E538D866-641A-4266-B1B8-5B7FC8CD5E15Q38865237-CBCD7436-7E5F-4048-802F-4D50F03C4043Q38893813-AB83C48B-B9FD-4603-883F-1D53DFCB738CQ38917334-64C5D623-E5C9-486E-9846-5C43018FDA8FQ38923186-1CDBBF7A-F199-448A-90E2-0F43D0A88DD6Q38976913-A8049228-8CEE-41E0-8FEC-4712E2EDAE59Q39496973-F3B73762-58D8-4CF9-8C89-FBA393A0E18FQ40380058-CFBEA6A0-F93B-48AF-8E50-24A4542915C0Q40503661-BDCAF202-A8B0-4B19-BEB9-4B9C895376D4Q41135669-A5A646BE-CDB6-43FE-92A9-F23158A4B4A9Q41178661-C4D2BB59-BE15-4597-8D6A-6E47A024BB21Q41196370-4E5F2AB2-9065-403A-B895-B2C7ECFA00FCQ41203571-FC4135B1-47A0-4DDD-9595-EDB5948CBF5CQ41569049-7DD5DF79-244D-4B47-ACBD-7CB1B9C05F3AQ41820098-CF5FBDC0-5CF1-4812-95A5-8C25B28390D8Q42315619-7E8849A8-561C-440B-8B55-3372397748FFQ42316765-DF710054-270C-4F4A-ADDA-C0F750A6B737Q43614261-4836CC1C-6A4D-48E5-813E-4662D1A203C6Q44534123-7B06D395-8EB0-4329-B31C-011CB01DD7B9Q44943861-53BC2AF6-C339-4A9F-9808-0E3DF1556754Q45384558-E9BCB7B1-22F7-4D9F-B2EA-192B72D2C003Q46117941-50E00F7C-450D-4F34-9A72-68ADC8118704Q46479925-04EDA363-1DC7-4782-B8A4-0AD9A4525A0AQ46781042-E0A70016-6E9E-46B7-9C33-09D32563F01EQ46810170-B3BF2F80-A33A-4697-A7BA-4D46FE645240Q47178972-C889EF7F-B64D-4F3C-B2C8-34FF45851541Q47240789-1D9B9C27-8EA7-4911-8BF4-0653E18ABE76
P2860
The importance of the self-assembly process to control mechanical properties of low molecular weight hydrogels.
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
The importance of the self-ass ...... ow molecular weight hydrogels.
@en
type
label
The importance of the self-ass ...... ow molecular weight hydrogels.
@en
prefLabel
The importance of the self-ass ...... ow molecular weight hydrogels.
@en
P2860
P356
P1476
The importance of the self-ass ...... low molecular weight hydrogels
@en
P2093
Jaclyn Raeburn
P2860
P304
P356
10.1039/C3CS60030K
P577
2013-06-01T00:00:00Z