about
Transformation and patterning of supermicelles using dynamic holographic assembly.Polymeric micelles, a promising drug delivery system to enhance bioavailability of poorly water-soluble drugs.Micellization of St/MMA gradient copolymers: a general picture of structural transitions in gradient copolymer micelles.Application of hydrophobically modified water-soluble polymers for the dispersion of hydrophobic magnetic nanoparticles in aqueous media.Cubosomes from hierarchical self-assembly of poly(ionic liquid) block copolymersSynthesis of poly(alpha,beta-[N-(2-hydroxyethyl)-L-aspartamide])-folate for drug delivery.Near-infrared-emissive polymersomes: self-assembled soft matter for in vivo optical imaging.Self-assembly of "patchy" nanoparticles: a versatile approach to functional hierarchical materials.Formulation and characterization of a porous, elastomeric biomaterial for vocal fold tissue engineering research.Supramolecular guests in solvent driven block copolymer assembly: From internally structured nanoparticles to micellesStopped-flow kinetic studies of the formation and disintegration of polyion complex micelles in aqueous solution.Bacteria-mimicking nanoparticle surface functionalization with targeting motifsCombinatorial screening for specific drug solubilizers with switchable release profiles.Impact of chain microstructure on solution and thin film self-assembly of PCHD-based semi-flexible/flexible diblock copolymers.Polymer-based therapeutics: nanoassemblies and nanoparticles for management of atherosclerosisMultiblock copolymers exhibiting spatio-temporal structure with autonomous viscosity oscillationMechano-Responsive Hydrogels Crosslinked by Block Copolymer Micelles.Expanding the morphology library of block copolymer self-assemblies with clews of tubules.Block copolymer micelles as delivery vehicles of hydrophobic drugs: micelle-cell interactions.Janus particles for biological imaging and sensing.Multi-stimuli responsive macromolecules and their assemblies.Nanoparticle Formation from Hybrid, Multiblock Copolymers of Poly(Acrylic Acid) and VPGVG PeptideFluorophore exchange kinetics in block copolymer micelles with varying solvent-fluorophore and solvent-polymer interactionspH-responsive polymeric micelles with core-shell-corona architectures as intracellular anti-cancer drug carriers.Nanotechnology controlled drug delivery for treating bone diseases.Aliphatic polyester polymer stars: synthesis, properties and applications in biomedicine and nanotechnology.Synthesis of terpolymers by click reactions.Thermosensitive polymeric micelles for targeted drug delivery.Amino-acid-based block copolymers by RAFT polymerization.Amphiphilic polymeric micelles as the nanocarrier for peroral delivery of poorly soluble anticancer drugs.Two-dimensional nanoarchitectonics: organic and hybrid materials.Drug delivery systems: Advanced technologies potentially applicable in personalized treatments.Self-assembly and chemical processing of block copolymers: a roadmap towards a diverse array of block copolymer nanostructures.Photoresponsive polymer nanocarriers with multifunctional cargo.Hierarchical molecular self-assemblies: construction and advantages.Noncovalent interaction-assisted polymeric micelles for controlled drug delivery.Nanogel--an advanced drug delivery tool: Current and future.Polymeric micelles for oral drug administration enabling locoregional and systemic treatments.Precise AuxPt₁-x Alloy Nanoparticle Array of Tunable Composition for Catalytic Applications.Radiolabeling polymeric micelles for in vivo evaluation: a novel, fast, and facile method.
P2860
Q27343091-C6F97592-E828-4F0D-988A-7EA95DA2B577Q30451024-A74D8D97-40C4-484C-8385-7DEC480D234DQ30666391-37134515-10AF-4676-8BB0-B53C9E161F1FQ30807694-14C686A3-8DBE-4644-8C8A-A15A4492276CQ30835311-B77B2FD2-CC2F-4E92-A019-9D6EEF172B63Q33581508-9BBA66E0-47AA-42C1-B609-EF2E75A10F63Q33864092-5FFA5649-FA18-4A21-AA3C-753E512032BDQ33868471-270CFD9C-7E58-4D77-859E-0EC41F3A7FD3Q34543576-713BDF4E-E861-4F77-BB16-E44FE3AE4F9CQ34708543-9296BDCE-EA7F-4D57-BF3E-FA1663A23E01Q35042112-09CA2289-C247-45CF-B422-27D34191445AQ35449429-1D480448-348F-45FE-9339-E132837EB1A5Q35537690-ED5266F1-1196-43E7-A842-5AED51428F2BQ35694630-02E93A78-9EE1-4CE0-B6AD-02C614250CE1Q35710262-4020B7C4-7224-46E3-9B27-1D8C4D461936Q36221619-5247F8EF-920D-4B63-8196-AB8CB550F245Q36282967-83E18B41-C855-45FA-82E2-C17FA607EB58Q36351754-4CDFA601-CDF5-40EE-8A24-B3A53F17E6D1Q36648447-D23052D2-5980-49AB-8D81-2BEBC19FE99CQ36984356-5FBAB0D4-00E1-470C-8086-DA54207B983FQ37086678-3B46AA5A-2A1D-4ADB-97B5-700B2EB1CCE8Q37112037-BF6DB771-4046-4334-9929-B223FAC3D877Q37151775-92AFEF55-AC09-4888-B17D-F732D32A99C4Q37386308-8CD2230B-C1D6-4363-B48C-DB424F8795EAQ37564501-A7EB8CEA-7C86-4016-8BA1-DB1CBAB6840EQ37809979-56B49632-3C94-4797-978F-CCFBF2978BE6Q37877222-99B6CCB8-788F-4AAA-B6CC-3927C0B1DF48Q37935027-D1D9717D-89DF-4B6B-B76B-BD56B9968942Q38003081-3FF90891-0005-47F8-9CE1-8BB6FADBBBC8Q38004050-501FD6FD-5904-47CA-9619-A2B2787B36D6Q38025316-DB17641D-54F2-4836-94F2-1C0F0481A8A4Q38063945-F7D0F80D-B870-43B4-B032-65C0CBF2F919Q38112363-FCF6C214-C41A-4B74-8F6E-985EA3F82678Q38168744-F61023A9-C2E8-4411-934A-46CCBF99AC90Q38210085-15DEDE06-8487-48F0-BCF9-F3EA8A704F0CQ38227515-13577158-4904-4308-9A6F-F9B07C510219Q38232948-05C98DD7-8A94-407E-9482-6EBBFA9CA3A3Q38250152-443F04D3-BBD2-44BA-AB84-AFD48744612AQ38300333-F24DCC23-4B97-42DB-8DDD-B7DC07D22962Q38327170-0C3F225B-78DE-4D99-83A2-ADB591263CB7
P2860
description
im Juli 2003 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в липні 2003
@uk
name
Micellization of block copolymers
@en
Micellization of block copolymers
@nl
type
label
Micellization of block copolymers
@en
Micellization of block copolymers
@nl
prefLabel
Micellization of block copolymers
@en
Micellization of block copolymers
@nl
P1476
Micellization of block copolymers
@en
P2093
P304
P356
10.1016/S0079-6700(03)00015-7
P407
P577
2003-07-01T00:00:00Z