Search results for "Synthetic polymer"

showing 5 items of 5 documents

Tunable and Large-Scale Model Network StarPEG-DNA Hydrogels

2021

The use of DNA as a building block in synthetic polymer hydrogels promises high levels of programmability regarding sol/gel temperatures, tunable bond lifetimes, biocompatibility, and interaction w...

Inorganic Chemistrychemistry.chemical_compoundMaterials sciencePolymers and PlasticsBiocompatibilitychemistryBlock (telecommunications)Organic ChemistrySelf-healing hydrogelsMaterials ChemistryNanotechnologySynthetic polymerDNAMacromolecules
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Scaffolds based on hyaluronan crosslinked with a polyaminoacid: Novel candidates for tissue engineering application

2008

New porous scaffolds, with a suitable hydrolytic and enzymatic degradation, useful for tissue engineering applications have been obtained by a carbodiimide mediated reaction between hyaluronan (HA) and a synthetic polymer with a polyaminoacid structure such as α,β-polyaspartylhydrazide (PAHy). Scaffolds with a different molar ratio between PAHy repeating units and HA repeating units have been prepared and characterized from a chemical and physicochemical point of view. Tests of indirect and direct cytotoxicity, cell adhesion, and spreading on these biomaterials have been performed by using murine L929 fibroblasts. The new biomaterials showed a good cell compatibility and ability to allow ce…

Materials scienceCompressive StrengthPolymersBiomedical EngineeringBiomaterialshyaluronanb-polyaspartylhydrazidechemistry.chemical_compoundMiceTissue engineeringMolar ratioCell MovementMaterials TestingCell AdhesionAnimalsHyaluronic AcidCytotoxicityCell adhesionCells CulturedCarbodiimideTissue EngineeringTissue Scaffoldstissue engineering hyaluronic acid chemical crosslinking composite scaffold polyasparthylhydrazideMetals and AlloysCell migrationchemical crosslinkinghyaluronan; a; b-polyaspartylhydrazide; chemical crosslinking; composite scaffolds; tissue engineeringSynthetic polymerPorous scaffoldchemistryChemical engineeringaCeramics and Compositescomposite scaffoldsPeptidesBiomedical engineering
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Biomolecular conjugation inside synthetic polymer nanopores via glycoprotein-lectin interactions

2011

We demonstrate the supramolecular bioconjugation of concanavalin A (Con A) protein with glycoenzyme horseradish peroxidase (HRP) inside single nanopores, fabricated in heavy ion tracked polymer membranes. Firstly, the HRP-enzyme was covalently immobilized on the inner wall of the pores using carbodiimide coupling chemistry. The immobilized HRP-enzyme molecules bear sugar (mannose) groups available for the binding of Con A protein. Secondly, the bioconjugation of Con A on the pore wall was achieved through its biospecific interactions with the mannose residues of the HRP enzyme. The immobilization of biomolecules inside the nanopore leads to the reduction of the available area for ionic tran…

NanometresSynthetic membraneTransport equationNanoporesInformation processingRectification propertiesCylinders (shapes)Materials TestingConcanavalin AGeneral Materials ScienceFunctional polymersConical nanoporeschemistry.chemical_classificationChemistryBlocking effectElectric rectifiersComputer simulationEnzymesData processingNanoporeEnzyme moleculesFunctional polymersMolecular imprintingPorosityBio-molecularInner wallsMolecular imprintingSupramolecular chemistryNanotechnologyHorseradish peroxidaseIonic transportsNanocapsulesBio-conjugationMoleculeParticle SizeAqueous solutionsGlycoproteinsBiomoleculesBioconjugationBiomoleculeNanostructuresModel simulationChemical engineeringModels ChemicalPolymer membraneConductance stateFISICA APLICADABiospecific interactionSynthetic polymersSugarsSupramolecular chemistryPore wallCarbodiimide-coupling chemistry
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Chemical Strategies for the Synthesis of Protein–Polymer Conjugates

2012

Protein-polymer conjugates have achieved tremendous attention in the last few years. The synergistic combination of properties has led to certain advantages in bio-applications. Over the past few years, numerous chemical strategies have been developed to conjugate different synthetic polymers onto proteins, most of which can be summarized within the scope of click-chemistry. Here we highlight conjugation strategies based on available functional groups present on the synthetic polymer and existing groups of proteins from the natural pool. In particular, the chapter organizes the various possible reactions by classes of functional groups present on protein surfaces, deriving from selected ami…

chemistry.chemical_classificationChemistryPosttranslational modificationClick chemistryPolymerAmino acid residueSynergistic combinationCombinatorial chemistrySynthetic polymerConjugateProtein polymer conjugates
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Post-Polymerization Modification

2012

The synthesis of functional polymers has been enriched dramatically by post-polymerization modifications. Even though it represents a synthetically very appealing approach, different synthetic concepts of organic reactions are utilized in polymer science for the synthesis of architecturally well-defined multifunctional polymers. The different classes of reactions that provide the synthetic polymer chemist with tools of unprecedented precision, thereby opening the doors for materials synthesis in an interdisciplinary world, will be summarized.

chemistry.chemical_classificationOrganic reactionChemistryClick chemistryOrganic chemistryNanotechnologyPolymerFunctional polymersPost polymerizationSynthetic polymer
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