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Highly structured pH-responsive honeycomb films by a combination of a breath figure process and in situ thermolysis of a polystyrene-block-poly(ethoxy ethyl acrylate) precursor
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- Journal Article
- A1
- open access
Development of optimized autonomous self-healing systems for epoxy materials based on maleimide chemistry
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- Journal Article
- A1
- open access
Redox-responsive degradable PEG cryogels as potential cell scaffolds in tissue engineering
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'Clicking' polymers or just efficient linking: what is the difference?
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Redox-responsive degradable PEG-cryogels as potential cell scaffolds in tissue engineering
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Norbornenyl-based RAFT agents for the preparation of functional polymers via thiol-ene chemistry
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Evaluation of degradable PEG-cryogels as potential cell scaffolds in tissue engineering
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Development of optimized autonomous self-healing systems based on highly efficient reactions
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- Journal Article
- A1
- open access
Effect of crosslinker multiplicity on the gel point in ATRP
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- Journal Article
- A1
- open access
Limitations of radical thiol-ene reactions for polymer-polymer conjugation
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Redox-responsive degradation of poly(ethylene glycol) (PEG) based cryogels
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Poly(ethylene glycol) based degradable cryogels
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'Thio-click' chemistry towards functional polymers: how to optimize it?
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Redox-responsive degradation of poly(ethylene glycol) (PEG) based cryogels
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Combination of RAFT and Thiol-ene chemistry toward functional polymers
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Chemical modifications of cryogels verified using high-resolution mass NMR spectroscopy
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Norbornenyl based raft agents for the preparation of functional polymers via thiol-ene click chemistry
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'Click' chemistry/ATRP combination for the design of poly(acrylic) acid containing polymers and the evaluation of polymeric ligands
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- Journal Article
- A1
- open access
Poly(acrylic acid) with disuffide bond for the elaboration of pH-responsive brush surfaces
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- Journal Article
- A1
- open access
Solvent-resistant nanofiltration for product purification and catalyst recovery in Click chemistry reactions
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Post-reaction catalyst purification of 'Click' chemistry products with solvent resistant nanofiltration (SRNF)
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Poly(ethylene glycol) (PEG) based cryogels with cleavable disulfide linkages
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Norbornenyl based raft agents for the preparation of functional polymers via thiol-ene click chemistry
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Limitations of radical thiol-ene reactions for polymer-polymer conjugations
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Thiol-mediated polymeric materials
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RAFT and thiol-ene chemistry toward functional polymers (Lect. by Milan)
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Combination of RAFT and thiol-ene chemistry toward functional polymers
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Network formation by free radical polymerization versus network formation by controlled radical polymerization/by thiol-ene 'click' chemistry: a single-molecule view
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‘Click’ functionalization of cryogels conveniently verified and quantified using high- resolution MAS NMR spectroscopy
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'Clicked' polymeric microcapsules and beads: azide-alkyne versus thiol-yne approach
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'Click' functionalization of cryogels easily verified using high-resolution MAS NMR spectroscopy
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Functionalization of cryogels: toward versatile macroporous materials
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Block versus block-like copolymers: synthesis and solid-liquid interface behavior
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'Clicked' polymeric microcapsules and beads: Azide-alkyne versus thiol-ene and thiol-yne approach (Abstract of Lecture)
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Comparative Study of the Solid-Liquid Interface Behavior of Amphiphilic Block and Block-Like Copolymers
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From novel block-like copolymers to reactive nanoparticles: ATRP and “click” chemistry as synthetic tools
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Facile access to an efficient solid-supported click catalyst system based on poly(ethyleneimine)
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Stimuli-responsive degradable cryogels
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Block copolymers via thiol-ene 'click' chemistry
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Gelation in ATRP: using branching agents with different functionality
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Biodegradable polymeric microcapsules via ‘click’ chemistry
(2009) p.P2-15-P2-15 -
Gelation in ATRP: Using branching reagents with different functionality
(2009) p.P2-49-P2-49 -
Chemical modifications of cryogels verified using high-resolution mass NMR spectroscopy
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'Clicked' microcapsules, beads and multilayers: azide-alkyne versus thiol-ene and thiolyne approach
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Block copolymers via thiol-ene 'click' chemistry
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Fabrication of porous 'clickable' polymer beads and rods through generation of high internal phase emulsion (HIPE) droplets in a simple microfluidic device
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From novel block-like copolymers to reactive nanoparticles: ATRP and "click" chemistry as synthetic tools
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Stimuli-responsive degradable cryogels (Poster presentation)
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Amphiphilic block versus ‘block-like’ copolymers prepared by ATRP: Synthesis, micellization and pigment stabilization
(2009) p.28-28 -
Gelation in ATRP: effect of cross-linker multiplicity
(2009) p.97-97 -
Exploration of novel functionalization concepts for surfaces, beads and microcapsules
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Combination of ATRP and Click chemistry for the design of poly(acrylic acid) containing polymers and the use of a new polymeric ligand
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Synthetic strategies for a range of pH-responsive polymer structures involving ATRP and 'click' chemistry
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Easy preparation of specialty polymers containing poly(acrylic acid)
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Amphiphilic block and "block-like" copolymers based on poly(isobornyl acrylate) and poly(acrylic acid) via ATRP (Poster by B.Dervaux)
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Cryogels as novel solid-supported copper catalyst system for click chemistry and their use in column reactors (Lect. by B. Dervaux)
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Synthetic strategies for a range of pH-responsive polymer structures involving ATRP and 'click' chemistry
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Poly-tetrahydrofuran/Clay Nanocomposites by In Situ Polymerization and “Click” Chemistry Processes (Poster presentation)
(2008) p.87-87 -
New Synthetic Routes for the Preparation of Polyether/Clay Nanocomposites
(2008) p.42-42 -
Biodegradable microgels by click chemistry
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ATRP and 'click' chemistry for the design of poly(acrylic acid) containing polymers and evaluation of a novel solid-supported Cu(I) catalyst system (Sh.Lect. by W. Van Camp)
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Stimuli-responsive degradable cryogels
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Using hr-MAS NMR to Monitor and Quantify Chemical Modifications of Cryogels
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Degradable microgels and hollow capsules by 'click' chemistry
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Cryogels as novel solid support for copper catalyzed "click" chemistry
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'Click' chemistry/ATRP combination for the design of poly(acrylic acid) containing polymers and the evaluation of polymeric ligands
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Chemical modifications of cryogels verified using high-resolution mass NMR spectroscopy
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Cryogels as novel solid support for continuous metal-catalyzed reactions
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A new macromolecular catalytic complex based on poly(ethylenimine) for "click" chemistry
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Polytetrahydro-furan/clay nanocomposites by cationic ring opening polymerization via in situ polymerization and "click" chemistry processes
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Biodegradable microcapsules designed via "click" chemistry
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Macroporous gels as column reactors: application for metal-catalyzed reactions
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Solvent resistant nanofiltration to retain ‘click’ oligomers/polymers while permeating homogeneous Cu catalysts and polara protic solvents (Poster)
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Using hr-MAS NMR to Monitor and Quantify Chemical Modifications of Cryogels
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Biodegradable microcapsules designed via 'click' chemistry
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Synthesis of poly(isobornyl acrylate) containing copolymers by atom transfer radical polymerization
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Polytetrahydrofuran/clay nanocomposites by in situ polymerization and "click" chemistry processes
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Degradable multilayer films and hollow capsules via a 'Click' strategy
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Controlled synthesis of amphiphilic block copolymers based on polyester and poly(amino methacrylate): Comprehensive study of reaction mechanisms
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Biodegradable microgels by click chemistry
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Novel strategies for the design of poly(acrylic acid) containing polymer structures using controlled radical polymerization (Lect. by W.VC)
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New poly(acrylic acid) containing segmented copolymer structures by combination of "click" chemistry and atom transfer radical polymerization
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Combination of ATRP and 'Click' chemistry for the design of poly(acrylic acid) containing polymer architectures
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Advanced pH-responsive polymer structures via combination of ‘click’ chemistry and Atom Transfer Radical polymerization (Poster of W.Van Camp)
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Amphiphilic block and ‘block-like’ copolymer structures based on poly(isobornyl acrylate) and poly(acrylic acid) via ATRP (Poster B.Dervaux)
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Combination of ATRP and ‘Click’ chemistry for the design of poly(acrylic acid)containing polymer architectures (Poster by W. Van Camp)
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Amphiphilic block and ‘block-like’ copolymer structures base don poly(isobornyl acrylate) and poly(acrylic acid) via ATRP. Poster P22 by B. Dervaux
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Combining a novel poly(acrylic acid) precursor approach and ‘click’ chemistry for the synthesis of diverse polymer structures. Oral Communication “OC5” by W. Van Camp
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New pH-responsive segmented copolymer structures by combination of « click » chemistry and Atom Transfer Radical Polymerization (Poster by W.Van Camp)
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Morphological transition during the thermal deprotection of poly(isobornyl acrylate)-b-poly(1-ethoxyethyl acrylate)
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- PhD Thesis
- open access
Novel Routes for the Design of Poly((meth)acrylic acid) Containing Polymer Structures by Controlled Radical Polymerization
(2007) -
Stimulus-responsive poly(acrylic acid) brushes on gold substrates (Poster by W.VCamp)
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How to deal with challenges to prepare well-defined poly(meth)acrylic acid) containig polymer structures by controlled radical polymerization? (Lecture by W.Van Camp)
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Novel developments in the design of near-monodisperse poly(acrylic acid) cntaining polymer architectures (Lecture by)
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Controlled radical polymerization of 1-ethoxyethyl (meth)acrylate: novel route for the synthesis of poly(meth)acrylic acid) containing polymer structures
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Synthese van goed gedefinieerde poly((meth)acrylzuur) bevattende polymeerstructuren via gecontroleerde radicalaire polymerisatie (Lezing dr. W. Van Camp)
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pH-Responsive diblock copolymers prepared by the dual initiator strategy
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Novel route towards near-monodisperse poly((meth)acrylic) containing polymer architectures
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Novel way towards well-defined pH-responsive polymer structures via controlled radical polymerization techniques (Abstract)
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Novel routes towards monodisperse poly((meth)acrylic acid) containing polymer structures (Lecture by F. Du Prez)