Bioinspired functional block copolymers
Identifieur interne : 002C05 ( Main/Exploration ); précédent : 002C04; suivant : 002C06Bioinspired functional block copolymers
Auteurs : Hans G. Börner [Allemagne] ; Helmut Schlaad [Allemagne]Source :
- Soft Matter [ 1744-683X ] ; 2007.
English descriptors
- Teeft :
- Achiral backbone, Acrylate, Aggregation, Aggregation process, Aggregation tendency, American chemical society, Amino, Amino acid, Amino acid residues, Amino acid sequence, Amino acids, Amylose, Angew, Aqueous solution, Aqueous solutions, Assembly process, Atom transfer, Atrp, Average number, Biomacromolecules, Block copolymers, Block copolypeptides, Boca raton, Borner, Broad spectrum, Chem, Colloid, Commun, Conformation, Conjugate, Conjugation, Cooperative manner, Copolymer, Copyright, Drug discovery, Duplex, Duplex formation, Entropic effect, Ethylene residues, External stimuli, Fibril, Fibrillar structures, Fibrillar tapes, Formation kinetics, Functionality, Genetic code, Gold colloids, Gold nanoparticles, Helical, Helix, Helmut schlaad, Hest, Hybrid, Hybrid copolymers, Hybridization, Hybridization event, Hydrogen bonds, Hydrophobic, Hydrophobic effect, Ionic strength, Klok, Krause, Lateral aggregation, Ligation, Linear conjugates, Macroinitiator, Macromol, Macromolecular chimeras, Macromolecule, Material science, Mechanical properties, Microstructure formation, Mirkin, Molecular weight, Monomer, Monomer sequence, Multiblock copolymers, Native chemical ligation, Nucleotide bases, Oligonucleotide, Oligonucleotides, Oligopeptide, Oligopeptide segment, Organic media, Organic solvents, Oxide, Peptide, Peptide core, Peptide domains, Peptide macroinitiator, Peptide segments, Peptide sequence, Peptide strands, Peptide synthesis, Peptide systems, Peptide unimer, Planck institute, Polydispersity index, Polym, Polymer, Polymer chain, Polymer chemists, Polypeptide, Polystyrene, Precise control, Present contribution, Rapid commun, Repetitive sequence, Research interests, Royal society, Schematic illustration, Schlaad, Secondary interactions, Secondary structure, Secondary structure effect, Small amounts, Soft matter, Specific interactions, Spherical micelles, Spider silk, Spps, Stevenson ranch, Structural transition, Structure formation, Superstructure, Synthetic oligonucleotides, Synthetic polymers, Tetrahedron lett, Tirrell, Transition temperature, Vesicle, Vesicle membrane.
Abstract
The diversity and complexity of structures and functions in synthetic polymer systems can be increased through conjugation with biological segments or, in other words, through generation of “polymer-bioconjugates” or “macromolecular chimeras”. The present contribution highlights major synthetic approaches toward sophisticated functional hybrid block copolymers and analyses of structure–function relationships.
Url:
DOI: 10.1039/b615985k
Affiliations:
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nanoparticles</term><term>Helical</term><term>Helix</term><term>Helmut schlaad</term><term>Hest</term><term>Hybrid</term><term>Hybrid copolymers</term><term>Hybridization</term><term>Hybridization event</term><term>Hydrogen bonds</term><term>Hydrophobic</term><term>Hydrophobic effect</term><term>Ionic strength</term><term>Klok</term><term>Krause</term><term>Lateral aggregation</term><term>Ligation</term><term>Linear conjugates</term><term>Macroinitiator</term><term>Macromol</term><term>Macromolecular chimeras</term><term>Macromolecule</term><term>Material science</term><term>Mechanical properties</term><term>Microstructure formation</term><term>Mirkin</term><term>Molecular weight</term><term>Monomer</term><term>Monomer sequence</term><term>Multiblock copolymers</term><term>Native chemical ligation</term><term>Nucleotide bases</term><term>Oligonucleotide</term><term>Oligonucleotides</term><term>Oligopeptide</term><term>Oligopeptide segment</term><term>Organic media</term><term>Organic solvents</term><term>Oxide</term><term>Peptide</term><term>Peptide core</term><term>Peptide domains</term><term>Peptide macroinitiator</term><term>Peptide segments</term><term>Peptide sequence</term><term>Peptide strands</term><term>Peptide synthesis</term><term>Peptide systems</term><term>Peptide unimer</term><term>Planck institute</term><term>Polydispersity index</term><term>Polym</term><term>Polymer</term><term>Polymer chain</term><term>Polymer chemists</term><term>Polypeptide</term><term>Polystyrene</term><term>Precise control</term><term>Present contribution</term><term>Rapid commun</term><term>Repetitive sequence</term><term>Research interests</term><term>Royal society</term><term>Schematic illustration</term><term>Schlaad</term><term>Secondary interactions</term><term>Secondary structure</term><term>Secondary structure effect</term><term>Small amounts</term><term>Soft matter</term><term>Specific interactions</term><term>Spherical micelles</term><term>Spider 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The present contribution highlights major synthetic approaches toward sophisticated functional hybrid block copolymers and analyses of structure–function relationships.</div></front></TEI><affiliations><list><country><li>Allemagne</li></country><region><li>Brandebourg</li></region><settlement><li>Potsdam</li></settlement></list><tree><country name="Allemagne"><region name="Brandebourg"><name sortKey="Borner, Hans G" sort="Borner, Hans G" uniqKey="Borner H" first="Hans G." last="Börner">Hans G. Börner</name></region><name sortKey="Borner, Hans G" sort="Borner, Hans G" uniqKey="Borner H" first="Hans G." last="Börner">Hans G. Börner</name><name sortKey="Schlaad, Helmut" sort="Schlaad, Helmut" uniqKey="Schlaad H" first="Helmut" last="Schlaad">Helmut Schlaad</name><name sortKey="Schlaad, Helmut" sort="Schlaad, Helmut" uniqKey="Schlaad H" first="Helmut" last="Schlaad">Helmut Schlaad</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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