Structure-Property Relationships in Some Novel Polyolefins

Dias, Peter Simon

17 June 2008

No description available.

Packaging

Plastics

Polymers

Ethyele octene

PP

Shish Kebab

Bruckner

Biaxially oriented polypropylene

BOPP

Strain recovery

Olefin block copolymer

OBC

propylene-ethylene

Semicrystalline elastomer

Adhesion

Polymers

Mircrolayers

Coextrusion

Elasticity

Fabrication of Block Copolymer Templated Mesoporous Metal Oxide Composites for Energy Storage Applications

Bhaway, Sarang M.

04 October 2016

No description available.

Chemistry

Energy

Engineering

Film Studies

Inorganic Chemistry

Materials Science

Morphology

Nanotechnology

Nanoscience

Polymer Chemistry

Polymers

Biodegradable hydrogels based on water-soluble chitosan for cell transplant

Gámiz González, Mª Amparo

02 November 2016

[EN] The aim of tissue engineering is to develop functional biological substitutes to replace or restore damaged tissues by preparing three-dimensional scaffolds able to accommodate cells plus signaling factors to promote the regeneration of damaged tissue. There is a special interest in developing scaffolds that while providing a favourable environment for cells also possess a degradation rate that can be adapted to the tissue's rate of regeneration. Scaffolds should be porous and possess a pore morphology adapted to the application for which they are designed. They must also be able to hold large quantities of water (hydrogels) while presenting suitable cell/biomaterial interaction. The aim of this thesis is to create chitosan-based three-dimensional porous structures with tunable degradation rates with particular interest in fast degradation rate. Hydrogels of block-copolymer networks were prepared to crosslink the chitosan (CHT) or carboxymethyl chitosan (CmCHT) with either a hydrophobic polymer of low molecular weight, such as poly(ε-caprolactone), (PCL) or a hydrophilic polymer such as poly(ethylene glycol), (PEG). The hypothesis was that the degradation of the cross-linker polymer leaves behind large water-soluble polymer chains (protonated chitosan or carboxymethyl chitosan). However, in spite of chitosan's favourable properties, the polymer has relatively slow biodegradation times in enzymatic media that contain lysozyme and even slower in hydrolytic conditions. Chitosan's physical and chemical properties largely depend on its deacetylation degree (DD). In order to analyze these properties, chitosan was synthesized with various DD ranging from 85% to 45%. Water absorption was seen to rise rapidly as deacetylation was reduced. This would appear to contradict the fact that chitin water absorption (low DD) is much lower than that of chitosan. In order to understand this behaviour, it was analyzed the dependence of the degree of network swelling on the parameters determined by the Flory Rhener theory, the elastic properties of the network and the density of the cross-linking according to the sample's water content. The thermal stability of chitosan according to its DD was analysed by thermogravimetry. Different methods were applied to obtain the activation energy. Electrospinning was chosen as the porous membrane preparation technique as it provides thin membranes that can be handled with fiber sizes in the order of microns. The influence of the electrospinning and cross-linking processes on the thermal stability of chitosan was analyzed. Chitosan and carboxymethyl chitosan hydrogels covalently cross-linked with short chains of poly(ε-caprolactone), (PCL) and poly(ethylene glycol) (PEG) were synthesized. The formation of networks was confirmed by solubility tests with appropriate solvents for each polymer. Hydrogels that absorbed large quantities of water were obtained, with values that ranged between 90 and 5000%. The calorimetric tests together with the Studies on the kinetics of hydrolytic and enzymatic biodegradation showed three different systems: CmCHT-PEG system that can be classified as stable hydrogel, CHT-PCL system as semidegradable hydrogel and degradable hydrogels with degradation kinetics in the order of days for the CmCHT-PCL system. Finally, biological studies were carried out on porous CmCHT-PCL hydrogels. Mesenchymal stem cells (MSCs) from pig adipose tissue were then cultivated and the results showed that these networks can be used in the organism in tissue engineering applications with degradation times of around a week. / [ES] La ingeniería tisular tiene como finalidad desarrollar sustitutos biológicos funcionales que reemplacen o restauren los tejidos dañados. Se trata de preparar andamiajes tridimensionales (scaffolds) que sean capaces de albergar células y factores de señalización que favorezcan la regeneración del tejido dañado. Existe un especial interés en el desarrollo de scaffolds que proporcionando un entorno favorable a las células, tengan una tasa de degradación que se adapte a velocidad de regeneración del tejido. Los scaffolds deben ser porosos y poseer una morfología del poro adaptada a la aplicación para la que son diseñados. Deben ser capaces de albergar gran cantidad de agua (hidrogeles) al tiempo que presentan una interacción célula/biomaterial adecuada. El objetivo de esta tesis es el de crear estructuras porosas tridimensionales basadas en quitosano con velocidades de degradación ajustables con particular interés en velocidades de degradación altas. Se han preparado hidrogeles de redes de copolimeros en bloque entrecruzando el quitosano, (CHT) o el carboximetil quitosano, (CmCHT) con un polímero hidrófobo de bajo peso molecular como la poli(ε-caprolactona), (PCL) o bien con un polímero hidrófilo como es el poli(etilenglicol), (PEG). La hipótesis de trabajo fue que la degradación del polímero que actúa como entrecruzador debe dejar grandes cadenas del polímero (quitosano protonado o carboximetil quitosano) que son solubles en agua. A pesar de las buenas propiedades del quitosano, el polímero presenta tiempos de biodegradación bastante lentos en medio enzimático conteniendo lisozima y aún más lentos en condiciones hidrolíticas. Las propiedades físico-químicas del quitosano dependen en gran medida del grado de desacetilación, DD. Con el fin de analizar dichas propiedades se ha llevado a cabo la síntesis de quitosano con DD variando entre 85% y el 45%. Se ha comprobado que la absorción de agua aumenta rápidamente a medida que el grado de desacetilación disminuye. Esto parece contradecir el hecho de que la absorción de agua de la quitina (DD bajo) es mucho menor que la de quitosano. Para entender dicho comportamiento se han analizado los parámetros que determinan la teoría de Flory Rhener, las propiedades elásticas de la red y la densidad de entrecruzamiento en función del contenido en agua de la muestra. La estabilidad térmica del quitosano en función de DD ha sido analizada por termogravimetría. Se han aplicado diferentes métodos para obtener la energía de activación. Como técnica de preparación de membranas porosas se ha elegido el electrohilado, ya que permite obtener membranas delgadas y manipulables con tamaños de fibra del orden de micras. Se ha analizado la influencia de los procesos de electrohilado y entrecruzamiento en la estabilidad térmica del quitosano. Se han sintetizado hidrogeles de quitosano, y carboximetil quitosano entrecruzados covalentemente con cadenas cortas de poli(ε-caprolactona), y poli(etilenglicol). La formación de las redes se ha confirmado mediante ensayos de solubilidad con buenos solventes para cada polímero. En todos los casos se han obtenido hidrogeles que absorben gran cantidad de agua con valores que oscilan entre 90 y 5000%. Los estudios de las cinéticas de biodegradación tanto hidrolítica como enzimática revelan la obtención de tres sistemas que se pueden clasificar como hidrogeles estables, para los hidrogeles formados por CmCHT-PEG, hidrogeles semidegradables para el sistema CHT-PCL y finalmente hidrogeles degradables con cinéticas de degradación del orden de días, para el sistema CmCHT-PCL. Finalmente se ha llevado a cabo estudios biológicos de los hidrogeles porosos de CmCHT-PCL. Se realizaron cultivos con células mesenquimales del tejido adiposo de cerdo (MSCs). Los resultados han revelado que dichas redes pueden ser utilizadas como sistemas de liberación de células en el organismo con tiempos de degradación / [CA] L'enginyeria tissular té com a finalitat desenvolupar substituts biològics funcionals que reemplacen o restauren els teixits danyats. Es tracta de preparar suports tridimensionals (esquelets o scaffolds) que siguen capaços d'albergar cèl.lules i factors de senyalització que afavorisquen la regeneració del teixit danyat. Hi ha un interès especial en el desenvolupament d'esquelets que, proporcionant un entorn favorable a les cèl.lules, tinguen una taxa de degradació que s'adapte a la velocitat de regeneració del teixit. Els scaffolds han de ser porosos i han de tenir una morfologia del porus adaptada a l'aplicació per a la qual són dissenyats. Han de ser capaços d'albergar una gran quantitat d'aigua (hidrogels) alhora que presenten una interacció cèl.lula/biomaterial adequada. L'objectiu d'aquesta tesi és crear estructures poroses tridimensionals basades en quitosan amb velocitats de degradació sintonizables amb un interés particular de rutes de degradació altes. S'han preparat hidrogels de xarxes de copolímers en bloc entrecreuant el quitosan o el carboximetil quitosan amb un polímer hidròfob de baix pes molecular com la poli (ε-caprolactona), o bé amb un polímer hidròfil com és el poli (etilenglicol). Es tracta d'aconseguir que quan el polímer que actua com a entrecreuador es degrade, deixe grans cadenes del polímer (quitosan protronat o carboximetil quitosan) que són solubles en aigua. A pesar de les bones propietats del quitosan, el polímer presenta cinètiques de biodegradació lentes en condicions enzimàtiques quan conté lisozima i encara més lentes en condicions hidrolítiques. Les propietats fisicoquímiques del quitosan depenen en gran mesura del grau de desacetilació, DD. A fi d'analitzar aquestes propietats, s'ha dut a terme la síntesi de quitosan amb un DD que variava entre el 85% i el 45%. S'ha comprovat que l'absorció d'aigua augmenta ràpidament a mesura que el grau de desacetilació disminueix. Això sembla que contradiu el fet que l'absorció d'aigua de la quitina (DD baixos) és molt menor que no la de quitosan. Per a entendre aquest comportament s'ha analitzat la dependència del grau d'unflament de la xarxa amb els paràmetres que determina la teoria de Flory Rhener, les propietats elàstiques de la xarxa i la densitat d'entrecreuament en funció del contingut en aigua de la mostra. L'estabilitat tèrmica del quitosan en funció del DD ha sigut analitzada per termogravimetria. S'han aplicat diversos mètodes per obtenir l'energia d'activació. Com a tècnica de preparació de membranes poroses s'ha utilitzat l'electrofilatura, ja que permet obtenir membranes primes i manipulables amb grandàries de fibra de l'ordre de micres. S'ha analitzat la influència dels processos d'electrofilatura i entrecreuament amb l'estabilitat tèrmica del quitosan. S'han sintetitzat hidrogels de quitosan i carboximetil quitosan entrecreuats covalentment amb cadenes curtes de poli(ε-caprolactona) i poli(etilenglicol). La formació de les xarxes s'ha confirmat per mitjà d'assajos de solubilitat amb bons solvents per a cada polímer. En tots els casos s'han obtingut hidrogels que absorbeixen una gran quantitat d'aigua, compresa en valors que oscil.len entre el 90 i el 5.000%. Els estudis de les cinètiques de biodegradació tant hidrolítica com enzimàtica revelen l'obtenció de tres sistemes que es poden classificar com a hidrogels estables (per als hidrogels formats per CmCHT-PEG), hidrogels semidegradables (per al sistema CHT-PCL) i, finalment, hidrogels degradables amb cinètiques de degradació de l'ordre de dies (per al sistema CmCHT-PCL). Finalment s'ha dut a terme estudis biològics dels hidrogels porosos de CmCHT-PCL. Es van realitzar cultius amb cèl.lules mesenquimals del teixit adipós de porc (MSCs). Els resultats han revelat que aquestes xarxes poden ser utilitzades com a sistemes d'alliberament de cèl.lules en l'organisme amb temps de degradació de l'ordre d'una setm / Gámiz González, MA. (2016). Biodegradable hydrogels based on water-soluble chitosan for cell transplant [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/73070

Chitosan

Block-copolymer networks.

Water-soluble chitosan

Degradation rate

Thermal analysis

Hydrophobic

Hydrophylic

Poly(ε -caprolactone)

MAQUINAS Y MOTORES TERMICOS

FISICA APLICADA

Templating gold nanoparticles on nanofibers using block copolymer thin films

Zhu, Hu

09 1900

No description available.

SERS

Nanofibres

Polystyrène-bloc-poly(4-vinylpyridine)

Adsorption

Trempage

Self-Assembly

Gold Nanoparticles

Substrate Curvature

Dip-Coating

Block Copolymer Adsorption

Block Copolymer Brush Layers

Polystyrene-block-poly(4-vinylpyridine)

Block Copolymers

Auto-Assemblage

Nanoparticules D'or

Courbure du Substrat

Couches Minces

Couches de Type Brosse

Thin Films

Copolymères à Blocs

Conjugated Polymer Brushes (Poly(3-hexylthiophene) brushes): new electro- and photo-active molecular architectures

Khanduyeva, Natalya

21 January 2009

The aim of the present work was to screen the main methods for the synthesis of conjugated polymers for their suitability in the preparation of conductive polymer brushes. The main focus was put on the grafting of intrinsically soluble substituted regioregular polyalkylthiophenes because of their excellent optoelectronic properties. The resulting polymer films were characterized and their optoelectrical properties studied. For the first time, a synthesis of conductive polymer brushes on solid substrates using “grafting-from” method was performed. The most important, from my opinion, finding of this work is that regioregular head-to-tail poly-3-alkylthiophenes – benchmark materials for organic electronics - can be now selectively grafted from appropriately-terminated surfaces to produce polymer brushes of otherwise soluble polymers - the architecture earlier accessible only in the case of non-conductive polymers. In particular, we developed a new method to grow P3ATs via Kumada Catalyst Transfer Polymerization (KCTP) of 2-bromo-5-chloromagnesio-3-alkylthiophene. Exposure of the initiator layers to monomer solutions leads to selective chain-growth polycondensation of the monomers from the surface, resulting into P3AT brushes in a very economical way. The grafting process was investigated in detail and the structure of the resulting composite films was elucidated using several methods. The obtained data suggests that the grafting process occurs not only at the poly(4-bromstyrene) (PS-Br)/polymerization solution interface, but also deeply inside the swollen PS-Br films, penetrable for the catalyst and for the monomer The grafting process was investigated in detail and the structure of the resulting composite film was elucidated using ellipsometry, X-ray Photoelectron Spectroscopy (XPS), Rutherford backscattering spectroscopy (RBS), and Conductive atomic force microscopy (C-AFM). The obtained data suggests that the grafting process occurs not only at the poly(4-bromostyrene), PS-Br/polymerization solution interface, but also deeply inside the swollen PS-Br film, which is penetrable for the catalyst and the monomer. The process results in an interpenetrated PS-Br/P3HT network, in which relatively short poly(3-hexylthiophene), P3HT grafts emanate from long, cross-linked PS-Br chains. A further method investigated during our work was to covalently graft regioirregular P3HT to substrates modified by macromolecular anchors using oxidative polymerization of 3HT with FeCl3. P3HT layers with variable thicknesses from 30 nm up to 200 nm were produced using two steps of polymerization reaction. The P3HT obtained by oxidative polymerization had always an irregular structure, which was a result of the starting monomer being asymmetric, which is undesired for electronic applications. The third method for the production of conductive polymer brushes was to graft regioregular poly(3,3''-dioctyl-[2,2';5',2'']terthiophene) (PDOTT) by electrochemical oxidative polycondensation of symmetrically substituted 3,3''-dioctyl-[2,2';5',2'']terthiophene (DOTT). A modification of the supporting ITO electrode by the self-assembled monolayers (SAMs) of compounds having polymerizable head-groups with properly adjusted oxidative potentials was found to be essential to achieve a covalent attachment of PDOTT chains. The polymer films produced show solvatochromism and electrochromism, as well as the previous two methods. After polymerization, the next step towards building organic electronic devices is applying the methods obtained in nano- and microscale production. Block copolymers constitute an attractive option for such surface-engineering, due to their ability to form a variety of nanoscale ordered phase-separated structures. However, block copolymers containing conjugated blocks are less abundant compared to their non-conjugated counterparts. Additionally, their phase behaviour at surfaces is not always predictable. We demonstrated in this work, how surface structures of non-conductive block copolymers, such as P4VP-b-PS-I, can be converted into (semi)conductive P4VP-b-PS-graft-P3HT chains via a surface-initiated polymerization of P3HT (Kumada Catalyst Transfer Polymerization (KCTP) from reactive surface-grafted block copolymers. This proves that our method is applicable to develop structured brushes of conductive polymers. We believe that it can be further exploited for novel, stimuli-responsive materials, for the construction of sensors, or for building various opto-electronic devices. The methods developed here can in principle be adapted for the preparation of any conductive block copolymers and conductive polymers, including other interesting architectures of conductive polymers, such as block copolymers, cylindrical brushes, star-like polymers, etc. To this end, one needs to synthesize properly-designed and multi-functional Ni-initiators before performing the polycondensation.

poly(3-hexylthiophene)

Ni-initiator

catalyst chain growth polymerization

polymer brushes

conjugated polymer brushes

photovoltaic

cyclic voltammetry

block copolymer

patterning

Self-assembled monolayer (SAM)

poly(3-hexylthiophene)

Ni-initiator

Polymer Bürsten

Konjugative Polymer Bürsten

Photovoltaik

zyklische Voltammetrie

Block Copolymer

Patterning

ddc:540

rvk:VK 8007

Conjugated Polymer Brushes (Poly(3-hexylthiophene) brushes): new electro- and photo-active molecular architectures

Khanduyeva, Natalya

16 January 2009

The aim of the present work was to screen the main methods for the synthesis of conjugated polymers for their suitability in the preparation of conductive polymer brushes. The main focus was put on the grafting of intrinsically soluble substituted regioregular polyalkylthiophenes because of their excellent optoelectronic properties. The resulting polymer films were characterized and their optoelectrical properties studied. For the first time, a synthesis of conductive polymer brushes on solid substrates using “grafting-from” method was performed. The most important, from my opinion, finding of this work is that regioregular head-to-tail poly-3-alkylthiophenes – benchmark materials for organic electronics - can be now selectively grafted from appropriately-terminated surfaces to produce polymer brushes of otherwise soluble polymers - the architecture earlier accessible only in the case of non-conductive polymers. In particular, we developed a new method to grow P3ATs via Kumada Catalyst Transfer Polymerization (KCTP) of 2-bromo-5-chloromagnesio-3-alkylthiophene. Exposure of the initiator layers to monomer solutions leads to selective chain-growth polycondensation of the monomers from the surface, resulting into P3AT brushes in a very economical way. The grafting process was investigated in detail and the structure of the resulting composite films was elucidated using several methods. The obtained data suggests that the grafting process occurs not only at the poly(4-bromstyrene) (PS-Br)/polymerization solution interface, but also deeply inside the swollen PS-Br films, penetrable for the catalyst and for the monomer The grafting process was investigated in detail and the structure of the resulting composite film was elucidated using ellipsometry, X-ray Photoelectron Spectroscopy (XPS), Rutherford backscattering spectroscopy (RBS), and Conductive atomic force microscopy (C-AFM). The obtained data suggests that the grafting process occurs not only at the poly(4-bromostyrene), PS-Br/polymerization solution interface, but also deeply inside the swollen PS-Br film, which is penetrable for the catalyst and the monomer. The process results in an interpenetrated PS-Br/P3HT network, in which relatively short poly(3-hexylthiophene), P3HT grafts emanate from long, cross-linked PS-Br chains. A further method investigated during our work was to covalently graft regioirregular P3HT to substrates modified by macromolecular anchors using oxidative polymerization of 3HT with FeCl3. P3HT layers with variable thicknesses from 30 nm up to 200 nm were produced using two steps of polymerization reaction. The P3HT obtained by oxidative polymerization had always an irregular structure, which was a result of the starting monomer being asymmetric, which is undesired for electronic applications. The third method for the production of conductive polymer brushes was to graft regioregular poly(3,3''-dioctyl-[2,2';5',2'']terthiophene) (PDOTT) by electrochemical oxidative polycondensation of symmetrically substituted 3,3''-dioctyl-[2,2';5',2'']terthiophene (DOTT). A modification of the supporting ITO electrode by the self-assembled monolayers (SAMs) of compounds having polymerizable head-groups with properly adjusted oxidative potentials was found to be essential to achieve a covalent attachment of PDOTT chains. The polymer films produced show solvatochromism and electrochromism, as well as the previous two methods. After polymerization, the next step towards building organic electronic devices is applying the methods obtained in nano- and microscale production. Block copolymers constitute an attractive option for such surface-engineering, due to their ability to form a variety of nanoscale ordered phase-separated structures. However, block copolymers containing conjugated blocks are less abundant compared to their non-conjugated counterparts. Additionally, their phase behaviour at surfaces is not always predictable. We demonstrated in this work, how surface structures of non-conductive block copolymers, such as P4VP-b-PS-I, can be converted into (semi)conductive P4VP-b-PS-graft-P3HT chains via a surface-initiated polymerization of P3HT (Kumada Catalyst Transfer Polymerization (KCTP) from reactive surface-grafted block copolymers. This proves that our method is applicable to develop structured brushes of conductive polymers. We believe that it can be further exploited for novel, stimuli-responsive materials, for the construction of sensors, or for building various opto-electronic devices. The methods developed here can in principle be adapted for the preparation of any conductive block copolymers and conductive polymers, including other interesting architectures of conductive polymers, such as block copolymers, cylindrical brushes, star-like polymers, etc. To this end, one needs to synthesize properly-designed and multi-functional Ni-initiators before performing the polycondensation.

info:eu-repo/classification/ddc/540

ddc:540

High χ block copolymers for sub 20 nm pitch patterning: synthesis, solvent annealing, directed self assembly, and selective block removal

Jarnagin, Nathan D.

13 January 2014

Block copolymer (BCP) thin film patterns, generated using directed self-assembly (DSA) of diblock copolymers, have shown excellent promise as templates for semiconductor device manufacturing since they have the potential to produce feature pitches and sizes well below 20 nm and 10 nm, respectively, using current 193 nm optical lithography. The goal of this work is to explore block copolymers with sufficient thermodynamics driving force (as described by the Flory Huggins interaction parameter, χ) for phase separation at these smallest lengths scales. Here, poly(styrene)-b-poly(hydroxystyrene) is investigated since the PHOST domain is known to form extensive hydrogen bond networks resulting in increased χ due to this strong enthalpic interaction. In this work, nitroxide mediated polymerization (NMP) techniques were utilized to produce PS-b-PHOST diblock copolymers with a range of molecular weights (5000-30000) with low PDI approaching 1.2. The phase separation of low molecular weight PS-b-PHOST on neutral underlayer substrates via solvent annealing provided thin film vertical lamellae with 13 nm pitch. These results illustrate the improved resolution of PS-b-PHOST compared with the current industry standard of PS-b-PMMA (with 20 nm pitch). The directed self assembly of lamellar PS-b-PHOST patterns with 18 nm pitch via graphoepitaxy is demonstrated. Also, a highly selective atomic layer deposition (ALD) and etch technique was investigated which provided selective block removal of (PS-b-PHOST) block copolymer patterns which initially exhibited no inherent etch contrast. In this process, the PS domain is removed leaving a high fidelity etch relief pattern of the original block copolymer template. Finally, an alternative system is presented, namely Poly(trimethylsilylstyrene)-block-poly(hydroxystyrene) (PTMSS-b-PHOST), which utilizes silicon containing functionality in one of the blocks, providing high etch contrast. PTMSS-b-PHOST patterns were also exposed to oxygen plasma allowing selective block removal of the PS domain without the need for additional ALD processing steps.

Block copolymer

Phase separation

Directed self-assembly

Poly(styrene)-b-poly(hydroxystyrene)

Atomic layer deposition

Reactive ion etch

Block copolymers

Diblock copolymers

Thin films

Self-assembly (Chemistry)

Linear block copolymers of L–lactide and 2–dimethylaminoethyl methacrylate : synthesis and properties

Kryuchkov, Maksym

02 1900

Part of the research described in this thesis is conducted in collaboration with Centre d' étude et de Recherche sur les Macromolécules (CERM), Université de Liège, Sart-Tilman, Belgium / Les copolymères séquencés amphiphiles sont très prometteurs pour des applications de technologie de pointe en raison de leur capacité à s'auto-assembler dans des structures bien organisées à l'échelle du micro– et du nanométre, et de leur sensibilité à des stimulations de différentes natures. La formation des nanomotifs bien ordonnés dans les films et/ou en masse fournit un substitut à la nanolithographie et est utile pour le design et l'ingénierie de nanomembranes et de matériaux nanoporeux. L'auto–assemblage dans des solvants sélectifs, en incluant la sensibilité au pH et à la température, peut être ajusté pour correspondre aux besoins de différentes applications biomédicales, telles que l’encapsulation et/ou relargage de médicaments, l'ingénierie de tissus, etc. Dans ce contexte, des copolymères séquencés de type L–lactide (LLA) et méthacrylate 2–diméthylaminoéthyl (DMAEMA) sont d’un grand intérêt. Comme le contrôle sur l'auto–assemblage des copolymères séquencés est permis au niveau moléculaire, il est très important de préparer des copolymères bien définis avec des longueurs de bloc prévisibles et de faible polydispersité. Ainsi, une partie de cette étude a été consacrée au développement de procédures synthétiques optimales et à la caractérisation détaillée de copolymères di– et triblocs de LLA et de PDMAEMA. Un outil simple pour déterminer la présence d'homo–PLLA résiduel a été développée; cela a permis de déterminer et d'expliquer plusieurs voies de synthèse indésirables. La dernière inclut la participation possible de l'amorceur bifonctionnel utilisé, et nous avons alors proposé un système alternatif d'amorceur bifonctionnel/catalyseur. La racémisation du LLA par les unités amine de (P)DMAEMA a été observée pendant la polymérisation, limitant ainsi l'utilisation première du bloc PDMAEMA pour la préparation des copolymères PLLA–b–PDMAEMA. Les études thermiques et de cristallisation, en incluant les copolymères séquencés partiellement quaternisés, ont révélé un retard significatif de la vitesse de cristallisation, en présence du bloc de PDMAEMA. Nous avons constaté que les blocs sont miscibles pour de faibles masses molaires et que la miscibilité partielle est maintenue après quaternisation. Selon la longueur et le taux de quaternisation du bloc PDMAEMA, la cristallisation du PLLA a été étudiée dans un environnement restreint et confiné, faiblement ou fortement. La torsion des lamelles cristallines observée pour certains copolymères biséquencés a été accentuée dans les copolymères triséquencés, où la formation de sphérolites annelés a été observée dans toutes les conditions thermiques utilisées. / Multi–functional amphiphilic block copolymers have much promise for various high technology applications thanks to the controlled stimuli–responsive self–assembly into well–organized structures on the micro– and nanometer scales. The formation of well–ordered nanopatterns in films and/or in bulk provides a competitive substitute to nanolithography and is useful in the design and engineering of nanomembranes and nanoporous materials. Solution self–assembly in selective solvents, including pH and temperature sensitivity, can be tuned to match the needs of different biomedical applications, such as drug encapsulation/delivery, tissue engineering, etc. In this context, block copolymers of L–lactide (LLA) and 2–dimethylaminoethyl methacrylate (DMAEMA) are of great interest. Since the control over self–assembly of block copolymer systems is enabled on a molecular level, it is of great importance to prepare well–defined block copolymers with predictable block lengths and low polydispersity. Thus, a major part of the research in this study was devoted to developing optimal synthetic procedures with detailed characterization of linear di– and triblock copolymers of LLA and PDMAEMA. A simple tool to determine homo–PLLA impurity was developed, which helped to determine and explain several undesired routes. The latter includes possible involvement of the bifunctional initiator used, and an alternative bifunctional initiator/catalyst system was proposed. Racemization of LLA by (P)DMAEMA moieties was observed during LLA polymerization thus limiting the utilization of PDMAEMA–first approach for the preparation of PLLA–b–PDMAEMA. Thermal and crystallization studies, including on quaternized block copolymers, revealed a significant retardation effect of the PDMAEMA block on the crystallization kinetics. The blocks were found to be miscible in the melt at low molecular weights, and maintained partial miscibility after quaternization. Depending on the length and the quaternization degree of PDMAEMA, PLLA crystallization was studied in a templated, soft or hard confinement environment. Crystalline lamellae twisting observed in certain diblock copolymers was facilitated in triblock copolymers, where the formation of banded spherulites was observed in all thermal conditions used.

Copolymères Séquencés

L–lactide

Méthacrylate

Octoate d′étain

Cristallisation

Avrami

Sphérolite

Amorceur bifonctionnel

Synthèse en une étape

Block copolymer

L–lactide

Methacrylate

Tin octoate

Crystallization

Avrami

Spherulite

Bifunctional Initiator

One–pot Synthesis

Vésicules polymères biorésorbables et stimulables pour des applications en vectorisation

Sanson, Charles

11 January 2010

L’auto-assemblage de copolymères à blocs amphiphiles est un outil puissant de la chimie supramoléculaire pour la conception de nano-objets complexes et fonctionnels. Dans ces travaux de thèse, l’étude approfondie d’un copolymère à blocs « hybride » synthétique-b-peptidique poly(triméthylène carbonate)-b-poly(acide glutamique) pour des applications de vectorisation a été menée. Des morphologies vésiculaires, obtenues par auto-assemblage en voie « co-solvant » et présentant une grande stabilité ainsi qu’un caractère stimulable ont été mises en évidence. Une transition inédite en température, par des phénomènes de fusion et de fission, a pu être observée. L’encapsulation dans ces vésicules polymères d’un principe actif anti-tumoral et de nanoparticules magnétiques, à des taux très élevés, permet d’améliorer le contraste en IRM ainsi que de moduler la libération de la molécule par une variation des paramètres environnementaux (pH, T) ou par un effet d’hyperthermie magnétique. / Block copolymer self-assembly is a powerful tool within supramolecular chemistry to design smart and functional nano-objects. In this thesis work, comprehensive study of hybrid poly(trimethylene carbonate)-b-poly(glutamic acid) block copolymers for drug delivery applications has been conducted. Highly stable vesicular morphologies presenting stimuli-responsive behaviour were prepared using a solvent-injection method. In particular, original temperature responsiveness mediated by fusion and fission events has been evidenced. Dual loading of an anticancer drug and superparamagnetic nanoparticles in these vesicles, at very high loading contents, allows enhancing MRI contrast and controlling drug release kinetics by varying environmental conditions (pH, T) or by using a magnetic hyperthermia effect.

Copolymères à blocs

Polypeptide

Polycarbonate

Vésicules

Polymèrosome

Auto-assemblage

Nanoprécipitation

Biodégradable

Stimulable

Doxorubicine

Délivrance contrôlée

Maghémite

Block copolymer

Polypeptide

Polycarbonate

Vesicle

Polymersome

Self-assembly

Nanoprecipitation

Biodegradable

Stimuli-responsive

Doxorubicin

Drug delivery

Controlled release

Synthèse de copolymères à architectures complexes à base de POE utilisés en tant qu'électrolytes polymères solides pour une application dans les batteries lithium métal-polymère

Gle, David

23 March 2012

Dans le contexte d'un développement durable, les véhicules électriques apparaissent comme une solution incontournable dans le futur. Parmi les dernières évolutions sur les batteries, les systèmes constitués d'une électrode au lithium (technologie lithium métal) présente des performances remarquables en termes de densité d'énergie. L'inconvénient majeur de cette méthodologie est lié à la formation de dendrites lors de la recharge susceptibles d'occasionner des courts-circuits conduisant à l'explosion de la batterie. C'est dans cet axe que s'inscrit mon sujet de thèse dont l'objectif est de développer un électrolyte polymère solide présentant une conductivité ionique élevée (2.10-4 S.cm-1 à40°C) et une tenue mécanique suffisante (30 MPa) pour limiter les phénomènes de croissance dendritique. Pour cela, la polymérisation contrôlée par les nitroxydes (NMP) a été utilisée pour synthétiser des copolymères à blocs avec un bloc possédant des groupes d'oxyde d'éthylène –CH2-CH2-O- permettant la conduction des ions lithium et un bloc de polystyrène assurant la tenue mécanique de l'électrolyte final. Le bloc assurant la conduction ionique des architectures ainsi synthétisées sont constituées soit de POE sous forme linéaire soit de POE sous forme de peigne. / In the context of sustainable development, electric vehicles appear to be a major solution for the future. Among the lastest technologies, the Lithium Metal Polymer battery has presented very interesting performances in terms of energy density. The main drawback of this system is the formation of lithium dendrites during the refill of the battery that could cause short circuits leading to the explosion of the battery. The aim of my PhD is to develop a Solid Polymer Electrolyte showing a high ionic conductivity (2.10-4 S.cm-1 at 40°C) and a high mechanical strength (30 MPa) to prevent dendritic growth. For that purpose, Nitroxide Mediated Polymerization is used to synthesize block copolymers with a PEO moiety for ionic conduction –CH2-CH2-O- and polystyrene for mechanical strength. Different kind of architectures have been synthesized : block copolymer with linear PEO moiety or with grafted PEO moiety.

Copolymères à Blocs

Electrolyte Polymère Solide

Batterie Lithium Métal Polymère

Poe

Ps

Mapeg

Nitroxide Mediated Polymerization

Block Copolymer

Solid Polymer Electrolyte

Lithium Metal Polymer Battery - PEO

Poe

Ps

Mapeg