Aqueous ATRP of amine-based methacrylates

Malet, Federic Louis Gino

January 2001

No description available.

541

Atom Transfer Radical Polymerisation

Synthetic and kinetic investigations into living free-radical polymerisation used in the preparation of polymer therapeutics

Adash, Uma

January 2006

The aim of this work was to successfully prepare polymers of N-(2-hydroxypropyl)methacrylamide, (PHPMA) using controlled/"living" free-radical polymerisation technique. For this purpose, atom transfer radical polymerisation (ATRP) and reversible addition-fragmentation (chain) transfer (RAFT) polymerisation were used in preparation of a number of base polymers with the intention of quantitatively converting them into PHPMA. Both methods were applied under varying polymerisation conditions, and the kinetics of the systems investigated. Various rate constants were measured, while computer modelling of the experimental data allowed estimation of other kinetic parameters of interest. Investigations into solvent and ligand effects on the kinetics of ATRP of the activated ester methacryloyloxy succinimide (MAOS) and one of the archetypal methacrylate monomers, methyl methacrylate (MMA) were carried out. The method of RAFT was also employed in polymerisation of MAOS and a number of other monomers in the hope of finding the best synthetic precursor of PHPMA. Polymers of methacryloyl chloride (MAC) and p-nitrophenyl methacrylate (NPMA) were prepared, as well as the polymers of HPMA itself and N-isopropyl methacrylamide. Polymerisation of MMA by RAFT was also attempted in view of adding to current knowledge on the monomer's behaviour and the kinetic characteristics of its RAFT polymerisation. Preparation of PHPMA from PMAOS, PMAC and PNPMA was attempted. Successful preparation of PHPMA from the polymer of the acid chloride was achieved under mild reaction conditions, while displacement of N-hydroxysuccinimide groups of PMAOS resulted in unexpected modification of the polymer under the conditions used. Conversion of PNPMA into PHPMA was not achieved. At this stage these results suggest inadequacy of both PMAOS and PNPMA as reactive polymeric precursors.

living free-radical polymerisation

atom transfer radical polymerisation

polymer therapeutics

Synthetic and kinetic investigations into living free-radical polymerisation used in the preparation of polymer therapeutics

Adash, Uma

January 2006

The aim of this work was to successfully prepare polymers of N-(2-hydroxypropyl)methacrylamide, (PHPMA) using controlled/"living" free-radical polymerisation technique. For this purpose, atom transfer radical polymerisation (ATRP) and reversible addition-fragmentation (chain) transfer (RAFT) polymerisation were used in preparation of a number of base polymers with the intention of quantitatively converting them into PHPMA. Both methods were applied under varying polymerisation conditions, and the kinetics of the systems investigated. Various rate constants were measured, while computer modelling of the experimental data allowed estimation of other kinetic parameters of interest. Investigations into solvent and ligand effects on the kinetics of ATRP of the activated ester methacryloyloxy succinimide (MAOS) and one of the archetypal methacrylate monomers, methyl methacrylate (MMA) were carried out. The method of RAFT was also employed in polymerisation of MAOS and a number of other monomers in the hope of finding the best synthetic precursor of PHPMA. Polymers of methacryloyl chloride (MAC) and p-nitrophenyl methacrylate (NPMA) were prepared, as well as the polymers of HPMA itself and N-isopropyl methacrylamide. Polymerisation of MMA by RAFT was also attempted in view of adding to current knowledge on the monomer's behaviour and the kinetic characteristics of its RAFT polymerisation. Preparation of PHPMA from PMAOS, PMAC and PNPMA was attempted. Successful preparation of PHPMA from the polymer of the acid chloride was achieved under mild reaction conditions, while displacement of N-hydroxysuccinimide groups of PMAOS resulted in unexpected modification of the polymer under the conditions used. Conversion of PNPMA into PHPMA was not achieved. At this stage these results suggest inadequacy of both PMAOS and PNPMA as reactive polymeric precursors.

living free-radical polymerisation

atom transfer radical polymerisation

polymer therapeutics

Synthesis and characterisation of block copolymers and cyclic polymers containing poly(p-phenylenevinylene)s

Lidster, Benjamin John

January 2015

Conjugated organic polymers have attracted immense interest for use in the active layer of photovoltaic cells, electroluminescent displays and diagnostic sensors. Precise control of the chemical structure of these conjugated materials is essential to achieve better device performance and certain structural aspects which have received minimal investigation include; the nature of the end groups, the precise control of the molecular weight and the formation of novel polymer topologies. Absolute control of these factors, in particular the end groups, has the potential to further tune the electro-optical properties, eliminate charge trapping and reactive sites, and facilitate block copolymer formation. The ring opening metathesis polymerisation of highly strained cyclophanediene monomers has proven to be an advantageous route to obtain soluble poly(p-phenylenevinylene)s (PPVs). In an extension of this previous work PPVs with both a pristine polymer backbone microstructure and a range of well-defined functional end groups have been prepared. These polymers exhibited excellent degrees of functionality, relatively narrow unimodal distributions and degrees of polymerisation much higher than those attainable by alternate routes. In particular the incorporation of an α-bromoester end group directly resulted in PPVs which were effective macroinitiators in the atom transfer radical polymerisation of methyl methacrylate. The diblock copolymers prepared by this route were isolated with narrow polydispersities, unimodal distributions and were free from homopolymer impurities. This method of preparing rod-b-coil diblock copolymers, where the properties of the two segments can readily be modified, provides access to materials which are of interest for both their self-assembly ability and for the development of a much required phase diagram in this area. Cyclic PPVs are of synthetic interest both for the absence of any end groups and for an infinitely long π-conjugated backbone, both of which are expected to contribute to unique electro-optical properties. The preparation of these target polymers was investigated by the ring expansion metathesis polymerisation of the cyclophanediene monomers. The formation of purely cyclic, low molecular weight PPVs was found to be highly dependent on both the reaction conditions used and the nature of the solubilising substituents. For example the preparation of purely cyclic PPVs with alkoxy side chains was unsuccessful, however the incorporation of alkyl side chains allowed for the successful isolation of the desired cyclic polymers.

668.9

Dendrimers and dendronized polymers : synthesis and characterization

Nyström, Andreas

January 2006

The goal of this work was to synthesize complex macromolecular architectures such as dendrimers and dendronized polymers, and evaluate the effect from the dendrons on the optical and material properties. The work presented in this doctoral thesis, Dendrimers and Dendronized Polymers - Synthesis and Characterization, is divided into one minor and one major part. The first part deals with the synthesis and characterization of two sets of dendritic porphyrins based on 2,2-bis(methylol)propionic acid (bis-MPA). The second part deals with the synthesis and characterization of dendronized poly(hydroxyl ethyl methacylate), dendronized poly(norbornene), and dendronized triblock copolymers, were the pendant dendrons are based on bis-MPA. Both free-base and zinc containing dendritic porphyrins was synthesized up to the fifth generation by employing iterative ester coupling utilizing the acetonide protected anhydride of bis-MPA as generic building block. First and second generation dendron bearing methacrylates based on 2-hydroxyethyl methacrylate were also synthesized by utilizing the acetonide protected anhydride of bis-MPA, and subsequently polymerized by atom transfer radical polymerization. By adopting a divergent “graft-to” approach starting from the first generation dendronized poly(hydroxyl ethyl methacrylate), well-defined dendronized polymers with acetonide, hydroxyl, acetate and hexadecyl surface functionality were obtained. By utilizing the same divergent iterative esterfication, first to fourth generation dendron functionalized norbornenes were synthesized. These monomers were polymerized by ring-opening metathesis polymerization, utilizing either Grubbs´ first or second generation catalyst. Acrylate functional first to fourth generation monomers were synthesized by the copper(I) catalyzed “click” coupling of azido functional dendrons and propargyl acrylate. The monomers were polymerized to dendronized triblock copolymers by reversible addition-fragmentation chain transfer polymerization, utilizing a difunctional poly(methyl methacrylate) as macro chain transfer agent. The bulk properties of the dendronized poly(hydroxyl ethyl methacrylate) and poly(norbornene) were investigated by dynamic rheological measurements and differential scanning calorimetry. It was found that all the acetonide functional bis-MPA based dendronized polymers had glass transitions temperatures in a similar range. The rheological behaviour showed that for the dendronized polymers having the same backbone length the complex viscosity as a function of functionality was independent of the surface functionality of the polymer. The generation number of the polymer had a profound influence on the complex viscosity, changing form a Newtonian behaviour to a shear thinning behaviour when the generation of the dendrons was increased from two to four. The dendronized poly(norbornene) had increasingly shorter backbone lengths for each generational increase, and for the materials set with comparably lower degree of polymerization, the G’ part of the complex modulus was mostly affected by attaching larger dendrons. In the case of the sample set of higher degree of polymerization, the second, third, and fourth generation samples had similar slopes of the G’ and G” curves, indicating a similar relaxation behaviour. / QC 20100914

Dendrimers

dendronized polymers

atom transfer radical polymerisation

ring-opening metathesis polymerization

2

2-bis(methylol)propionic acid

tri-block copolymers

rheology

differential scanning calorimerty

1H-NMR self-diffusion

Polymer chemistry

Polymerkemi

Controlled and localized synthesis of molecularly imprinted polymers for chemical sensors / Synthèse localisée et contrôlée de polymères à empreintes moléculaires pour capteurs chimiques

Kaya, Zeynep

05 November 2015

Les polymères à empreintes moléculaires (MIP), également appelés "anticorps en plastique", sont des récepteurs biomimétiques synthétiques qui sont capables de reconnaître et lier une molécule cible avec une affinité et une spécificité comparables à celles des récepteurs naturels tels que des enzymes ou des anticorps. En effet, les MIP sont utilisés comme éléments de reconnaissance synthétiques dans les biocapteurs et biopuces pour la détection de petits analytes et les protéines. La technique d'impression moléculaire est basée sur la formation de cavités de reconnaissance spécifiques dans des matrices polymères par un procédé de moulage à l'échelle moléculaire. Pour la conception de capteurs et biopuces, une cinétique d'adsorption et une réponse du capteur rapide, l'intégration des polymères avec des transducteurs, et une haute sensibilité de détection sont parmi les principaux défis. Dans cette thèse, ces problèmes ont été abordés par le développement de nanocomposites MIP / d'or via le greffage du MIP sur les surfaces en utilisant des techniques de polymérisation dédiées comme l'ATRP qui est une technique de polymérisation radicalaire contrôlée (CRP). Ces techniques CRP sophistiquées sont en mesure d'améliorer considérablement les matériaux polymères. L'utilisation de l'ATRP dans le domaine de MIP a été limitée jusqu'à présent en raison de son incompatibilité inhérente avec des monomères acides comme l'acide méthacrylique (MAA), qui est de loin le monomère fonctionnel le plus largement utilisé dans les MIP. Ici, un nouveau procédé est décrit pour la synthèse de MIP par ATRP photo-initiée utilisant fac-[Ir(Ppy)3] comme catalyseur. La synthèse est possible à température ambiante et est compatible avec des monomères acides. Cette étude élargit considérablement la gamme de monomères fonctionnels et de molécules empreintes qui peuvent être utilisés lors de la synthèse de MIP par ATRP. La méthode proposée a été utilisée pour la fabrication de nanocomposites hiérarchiquement organisés sur des surfaces métalliques nanostructurés avec des nano-trous et nano-ilots, présentant des effets plasmoniques pour l'amplification du signal. La synthèse de films de MIP à l'échelle du nanomètre localisés sur la surface d'or a été démontrée. Des méthodes de transduction optiques, à savoir la résonance de plasmons de surface localisée (LSPR) et la spectroscopie Raman exaltée par effet de surface (SERS) ont été exploitées. Ces techniques se sont montrées prometteuses pour l'amélioration de la limite de détection dans la détection d'analytes biologiquement pertinents, y compris les protéines et le médicament propranolol. / Molecularly imprinted polymers (MIPs), also referred to as plastic antibodies, are synthetic biomimetic receptors that are able to bind target molecules with similar affinity and specificity as natural receptors such as enzymes or antibodies. Indeed, MIPs are used as synthetic recognition elements in biosensors and biochips for the detection of small analytes and proteins. The molecular imprinting technique is based on the formation of specific recognition cavities in polymer matrices by a templating process at the molecular level. For sensor and biochip development, fast binding kinetics of the MIP for a rapid sensor response, the integration of the polymers with transducers, and a high sensitivity of detection are among the main challenges. In this thesis, the above issues are addressed by developing MIP/gold nanocomposites by grafting MIPs on surfaces, using dedicated techniques like atom transfer radical polymerization (ATRP) which is a versatile controlled radical polymerization (CRP) technique. Theses ophisticated CRP techniques, are able to greatly improve the polymeric materials. The use of ATRP in the MIP field has been limited so far due to its inherent incompatibility with acidic monomers like methacrylic acid (MAA), which is by far the most widely used functional monomer. Herein, a new method is described for the MIP synthesis through photo-initiated ATRP using fac-[Ir(ppy)3] as ATRP catalyst. The synthesis is possible at room temperature and is compatible with acidic monomers. This study considerably widens the range of functional monomers and thus molecular templates that can be used when MIPs are synthesized by ATRP. The proposed method was used for fabrication of hierarchically organised nanocomposites based on MIPs and nanostructured metal surfaces containing nanoholes or nanoislands, exhibiting plasmonic effects for signal amplification. The fabrication of nanometer scale MIP coatings localized on gold surface was demonstrated. Optical transduction methods, namely Localized Surface Plasmon Resonance (LSPR) and Surface Enhanced Raman Spectroscopy (SERS) were exploited and shown that they hold great promise for enhancing the limit of detection in sensing of biologically relevant analytes including proteins and the drug propranolol.

MIP

Polymérisation vivante

Couplage aryle diazonium

Nanocapteurs plasmoniques

Biomimétisme

Cinétique d'adsorption

Nanocomposites

Récepteurs

Molecularly imprinted polymer

Living polymerization

Aryl diazonium coupling

Iridium catalyst

Plasmonic nanosensor

Localized surface plasmon resonance