Global ETD Search

41	Applications of Thiele's ester derivatives from biological to material Chen, Jun 28 May 2018 (has links) Building upon existing synthetic methods, we have optimized the synthesis of Thiele’s methyl ester to an efficient and scalable methodology. As part of a study of chemo- and regioselective transformations within the Thiele’s ester scaffold, we designed and synthesized a new suite of molecular scaffolds incorporating a broad range (from 123° to 176°) of cleft angles. In addition to this, we compared two competing conceptual models for their ability to rationalize the selective formation of Thiele’s ester and two minor regioisomers which arise during the formation of the target product. We found that radical stabilization arguments (based on Deslongchamps’ seminal work) outperformed the classic frontier molecular orbital theory model in predicting the regioselectivity of Thiele’s ester dimerization. When this method was combined with simple steric arguments, we arrived at a general algorithm to rationalize Thiele type dimerization, including all the known homo- and heterodimerizations in the literature as well as a novel phosphine oxide-containing Thiele acid analogue discovered as part of this thesis work. In order to stimulate the use of Thiele’s ester chemistry in a diverse range of applications, we took advantage of our Thiele’s ester methodology to achieve a mono ester-substituted dicyclopentadiene (colloquially referred to as a “half” Thiele’s ester), and used this as the precursor of a novel functionalized polydicyclopentadiene (fPDCPD) ROMP polymer. The resulting fPDCPD has the highest glass-transition temperature reported for any polydicyclopentadiene material and allows for the facile manipulation of the surface chemistry through alteration of the embedded functional group. A long-term goal in the Wulff lab is to use Thiele’s ester as a scaffold for the generation of conformationally restricted (“peramivir-like”) neuraminidase inhibitors. Setting the groundwork for this, we explored the selectivity of various peramivir derivatives toward group-1 vs. group-2 neuraminidase enzymes. To this end, we coupled a wide range of alkyl chains and aromatic rings with different length and size parameters onto the primary amine of peramivir. We found that our de-guanidinylated peramivir analogues showed a rare target selectivity against group-2 neuraminidases instead of group-1 neuraminidases, which might due to the ring geometry of peramivir as well as the reduced electrostatic interaction between the amino group from our analogues and the Asp147-His150 residues from the enzyme. This suggested that it is possible for group-2 neuraminidases to have a more open 150-cavity state than group-1 neuraminidases. Additionally, the respectable IC50 values for these compounds, together with their significantly reduced polarity (relative to peramivir itself) may prove advantageous from a bioavailability standpoint. / Graduate / 2019-04-30 Thiele's ester poly dicyclopentadiene neuraminidase
42	pH Dependence of Acrylate-Derivative Polyelectrolyte Properties Swift, Thomas 07 May 2018 (has links) yes / There are many polymers formed of acrylate monomers in existence. Here we interrogate four commonly-used examples and study how their solution properties are pH dependent, or how their state of ionisation can affect their solution properties. Poly(acrylic acid) and poly(methacrylic acid) are both polyelectrolytes, with ionisable functional groups that make them stimuli responsive, changing their hydrodynamic volume. Poly(acrylamide) is a mass-produced material used in a variety of industrial applications, often with an anionic and cationic co-monomer, which dictates both its efficacy and impact on the environment. Poly(N-isopropyl acrylamide) is a thermally responsive material with applications in smart bioengineering. In solution, these materials can interact with each other due to competing hydrogen bonding interactions. However, this interpolymer complexation is dependent on both the ionisation, and the conformational state, of the polymers involved. This review focuses on the results from fluorescence tagging and turbidimetric techniques. Poly(acrylic acid) Poly(methacrylic acid) Poly(acrylamide) Poly(N-isopropylacrylamide) Stimuli responsive Interpolymer complexation Hydrodynamic volume Solution properties
43	Interactome des intervenants dans le métbolisme du poly(ADP-ribose) Isabelle, Maxim 19 April 2018 (has links) La poly(ADP-ribose) polymerases consistant en une population hétérogène de polymères formés à partir du NAD. La poly(ADP-ribose) glycohydrolase est responsable de la dégradation du poly(ADP-ribose). Les activités enzymatiques de ces enzymes constituent un système de régulation pour différents sentiers métaboliques. En effet, l'interaction démontrée entre le pADPr et de multiples protéines a permis de confirmer un rôle de modulateur de nombreuses voies de signalisation tel que la réparation de l'ADN, apoptose, cycle cellulaire, surveillance de l'intégrité du génome, transcription et modulation de la chromatine. Ainsi, nous avons formulé l'hypothèse que le pADPr pourrait coordonner la réparation des lésions à l'ADN et la progression du cycle cellulaire avec la signalisation d'événement apoptotiques. Une approche efficace constituerait à identifier et caractériser les protéines (intermédiaires) associées au pADPr selon une logique temporelle. Les diverses actions du pADPr sur les processus biologiques dépendent (dans le cas de la majorité du pADPr, soit celui métabolisé par PARP-1) de la gravité des dommages induits à l'ADN. Par conséquent, il existe probablement des points de seuil faisant basculer les voies de signalisation de la réparation vers la mort cellulaire. Une approche réductionniste, dans ce type de problème, ne peut apporter des réponses satisfaisantes. L'utilisation de la protéomique quantitative semble être une approche plus appropriée. Un volet du travail présenté dans cette thèse visait à identifier des partenaires des PARP-1, PARP-2 et PARG dans le but de reconnaître les sentiers biochimiques qui pourraient inclure une composante de poly(ADP-ribosylation) dans leur régulation et définir des interactions fonctionnellement pertinentes. Par la suite, nous avons établi un réseau dynamique des complexes associés au pADPr en fonction du temps suivant un dommage alkylant induit par un stress génotoxique. Ainsi, certains événements modulés par le pADPr ont été analysés et cartographies. De plus, nous avons caractérisé un rôle novateur du pADPr dans la formation des granules de stress suite à un stress génotoxique. En conséquence, nos résultats ont permis d'édifier les premières bases pour la biologie des systèmes de la poly(ADP-ribosyl)ation en fournissant un répertoire d'interactions protéique exhaustif.
44	Strategies for structural studies of poly(ADP-ribose) glycohydrolase: Towards the validation of a novel therapeutic target Botta, Davide January 2010 (has links) Poly(ADP-ribosyl)ation is a reversible post-translational modification of histones and nuclear proteins rapidly stimulated by DNA damage. Its homeostasis is a dynamic process regulated by the synthesizing enzymes poly(ADP-ribose) polymerases (PARPs) and the degrading enzyme poly(ADP-ribose) glycohydrolase (PARG). PARP-1, the first-discovered and major PARP, has been the focus of many studies aimed at clarifying the biological function of poly(ADP-ribose) (PAR). This abundant nuclear enzyme plays key roles in a variety of cellular processes, including the regulation of chromatin structure, transcription and genomic integrity. Its multifunctionality has made it an attractive and potential target for therapy, as evidenced by the numerous PARP-1 inhibitors currently undergoing clinical trials. The transient nature of PAR, explained by the close coordination between PARP-1 and PARG, has also highlighted the potential of targeting PARG for diseases of inappropriate cell death. A number of obstacles, however, have prevented PARG from being studied as extensively as PARP-1. The extreme sensitivity of PARG to proteases and its insolubility at high concentrations have limited structure-activity relationship analyses and structural studies of PARG, and the unavailability of high-throughput activity assays has stalled the discovery and development of specific and cell permeable PARG inhibitors, subsequently slowing down the validation of PARG as a therapeutic target. The work presented in this dissertation describes in detail strategies devised to overcome these difficulties. First, a novel colorimetric high-throughput assay for PARG was evaluated and its sensitivity and precision were compared to a widely-used radiolabelling assay. Second, several expression and purification systems were constructed in order to obtain high quantities of soluble human PARG protein adequate for in vitrostructural studies. The efficacy of these strategies was demonstrated in structure-activity analyses of PARG which led to the identification of a regulatory segment far removed linearly from the catalytic site of PARG. This region, necessary for catalytic activity, corresponds with a recently identified mitochondrial targeting sequence (MTS) and was thus named the ‘regulatory segment/MTS’ (REG/MTS). Finally, based on structural data obtained, secondary structure predictions were made to provide insight into the molecular composition of the different domains of PARG, whose structures still remain to be determined. nicotinamide adenine dinucleotide poly(ADP-ribose) poly(ADP-ribose) glycohydrolase poly(ADP-ribose) polymerase
45	Effect of Partial Poly (ADP-ribose) Glycohydrolase Gene Deletion on Cellular Responses to Genotoxic Stress Gao, Hong January 2006 (has links) Polymers of ADP-ribose (PAR) are rapidly synthesized by poly(ADPribose) polymerases (PARPs) and rapidly degraded by poly(ADP-ribose) glycohydrolase (PARG) following genotoxic stress. Since PAR metabolism plays an important role in cell fate determination following genotoxic stress, enzymes involved in PAR metabolism potentially represent promising therapeutic targets for modulating diseases of inappropriate cell proliferation or death. PARP-1 has been well validated and several PARP-1 inhibitors are currently being evaluated in clinical trials for cancer and ischemia treatment. In contrast, the biological function of PARG is still poorly understood. Due to low abundance of protein levels in mammalian cells and its unique substrate, PARG potentially represents another attractive target for pathological conditions mentioned above. PARG-Δ2,3 cells derived from homozygous PARG-Δ2,3 mice with targeted disruption of exons 2 and 3 of the PARG gene are used in this dissertation. The nuclear isoform PARG60 in PARG-Δ2,3 cells lacks the putative regulatory domain A compared to the nuclear isoform PARG110 in wild type cells. We report in this dissertation that PARG-Δ2,3 cells accumulate less PAR in spite of more rapid depletion of NAD following treatment with N-methyl- N’- Nitro-N-Nitrosoguanidine (MNNG). The estimation of PARP and PARG activity in intact cells shows increased activity of both enzymes in PARG-Δ2,3 cells following MNNG treatment, indicating the important role of domain A in the regulation of PARG and PARP activity under these conditions. Following MNNG treatment, PARG-Δ2,3 cells show reduced formation of XRCC1 foci, decreased H2AX phosphorylation, decreased DNA break intermediates during repair, and increased cell death. The altered PAR metabolism and defective cellular responses related to DNA repair in PARG-Δ2,3 cells may contribute to increased sensitivity of these cells to MNNG. Studies presented in this dissertation clearly demonstrate the important role of PARG110 in PAR metabolism and cellular responses to genotoxic stress, and thus provide supportive data for the validation of PARG as a promising potential therapeutic target. poly(ADP-ribose) glycohydrolase poly(ADP-ribose) poly(ADP-ribose) polymerase MNNG genotoxic stress NAD
46	Non-covalent Intermolecular Interactions in Polymer Design: Segmented Copolymers to Non-viral Gene Delivery Vectors Buckwalter, Daniel James 01 June 2013 (has links) Non-covalent intermolecular interactions play a large role in determining the properties of a given system, from segmented copolymers to interactions of functionalized polymers with non-viral nucleic acids delivery vehicles. The ability to control the intermolecular interactions of a given system allow for tailoring of that system to yield a desired outcome, whether it is a copolymers mechanical properties or the colloidal stability of a pDNA-delivery vector complex. Each chemical system relies on one or more types of intermolecular interaction such as hydrogen bonding, cooperative À-À stacking, electrostatic interactions, van der waals forces, metal-ligand coordination, or hydrophobic/solvophobic effects. The following research describes the tailoring of specific intermolecular interactions aimed at altering the physical properties of segmented copolymers and non-viral gene delivery vectors. Amide containing segmented copolymers relies heavily on hydrogen bonding intermolecular interactions for physical crosslinking to impart the necessary microphase separated morphology responsible for a copolymers physical properties. Amide containing hard segments are composed of various chemical structures from crystalline aramids to amorphous alkyl amides with each structure possessing unique intermolecular interactions. Variations to either of the copolymer segments alters the copolymers physical properties allowing for tuning of a copolymers properties for a particular application. The synthetic strategies, structure-property relationships, and physical properties of amide containing segmented copolymers are thoroughly reported in the literature. Each class of segmented copolymer that contain amide hydrogen bonding groups exhibits a wide range of tunable properties desirable for many applications. The segmented copolymers discussed here include poly(ether-block-amide)s, poly(ether ester amide)s, poly(ester amide)s, poly(oxamide)s, PDMS polyamides, and polyamides containing urethane, urea, or imide groups. The structure-property relationships (SPR) of poly(oxamide) segmented copolymers is not well understood with only one report currently found in literature. The effects of oxamide spacing in the hard segment and molecular weight of the soft segments in PDMS poly(oxamide) segmented copolymers demonstrated the changes in physical properties associated with minor structural variations. The optically clear PDMS poly(oxamide) copolymers possessed good mechanical properties after bulk polymerization of ethyl oxalate terminated PDMS oligomers with alkyl diamines or varied length. FTIR spectroscopy experiments revealed an ordered hydrogen bonding carbonyl stretching band for each copolymer and as the spacing between oxamide groups increased, the temperature at which the hard segment order was disrupted decreased. The increased spacing between oxamide groups also led to a decrease in the flow temperature observed with dynamic mechanical analysis. Copolymer tensile properties decrease with increased oxamide spacing as well as the hysteresis. The structure-property investigations of PDMS poly(oxamide) segmented copolymers showed that the shortest oxamide spacing resulted in materials with optimal mechanical properties. A new class of non-chain extended segmented copolymers that contained both urea and oxamide hydrogen bonding groups in the hard segment were synthesized. PDMS poly(urea oxamide) (PDMS-UOx) copolymers displayed thermoplastic elastomer behavior with enhanced physical properties compared to PDMS polyurea (PDMS-U) controls. Synthesis of a difunctional oxamic hydrazide terminated PDMS oligomer through a two-step end capping procedure with diethyl oxalate and hydrazine proved highly efficient. Solution polymerization of the oxamic hydrazide PDMS oligomers with HMDI afforded the desired PDMS-UOx segmented copolymer, which yielded optically clear, tough elastomeric films. Dynamic mechanical analysis showed a large temperature insensitive rubbery plateau that extended up to 186 ÚC for PDMS-UOx copolymers and demonstrated increased rubbery plateau ranges of up to 120 ÚC when compared to the respective PDMS-U control. The increase in thermomechanical properties with the presence of oxamide groups in the hard segment was due to the increased hydrogen bonding, which resulted in a higher degree of microphase separation. DMA, SAXS, and AFM confirmed better phase separation of the PDMS-UOx copolymers compared to PDMS-U controls and DSC and WAXD verified the amorphous character of PDMS-UOx. Oxamide incorporation showed a profound effect on the physical properties of PDMS-UOx copolymers compared to the controls and demonstrated promise for potential commercial applications. Two novel segmented copolymers based on a poly(propylene glycol) (PPG) that contained two or three oxamide groups in the hard segment were synthesized. Synthesis of non-chain extended PPG poly(trioxamide) (PPG-TriOx) and PPG poly(urea oxamide) (PPG-UOx) segmented copolymers utilized the two-step end-capping procedure with diethyl oxalate and hydrazine then subsequent polymerization with oxalyl chloride or HMDI, respectively. The physical properties of the PPG-TriOx and PPG-UOx copolymers were compared to those of PPG poly(urea) (PPG-U) and poly(oxamide) (PPG-Ox) copolymers. FTIR studies suggested the presence of an ordered hydrogen bonded hard segment for PGG-TriOx and PPG-Ox copolymers with PPG-TriOx possessing a lower energy ordered hydrogen bonding structure. PPG-UOx copolymers exhibited a larger rubbery plateau and higher moduli compared to PPG-U copolymers and also a dramatic increase in the tensile properties with the increased hydrogen bonding. The described copolymers provided a good example of the utility of this new step-growth polymerization chemistry for producing segmented copolymers with strong hydrogen bonding capabilities. Non-viral nucleic acid delivery has become a hot field in the past 15 years due to increased safety, compared to viral vectors, and ability to synthetically alter the material properties. Altering a synthetic non-viral delivery vector allows for custom tailoring of a delivery vector for various therapeutic applications depending on the target disease. The types of non-viral delivery vectors are diverse, however the lack of understanding of the endocytic mechanisms, endosomal escape, and nucleic acid trafficking is not well understood. This lack of understanding into these complex processes limits the effective design of non-viral nucleic acid delivery vehicles to take advantage of the cellular machinery, as in the case of viral vectors. Mechanisms for cellular internalization of polymer-nucleic acid complexes are important for the future design of nucleic acid delivery vehicles. It is well known that the mammalian cell surface is covered with glycosaminoglycans (GAG) that carry a negative charge. In an effort to probe the effect of GAG charge density on the affinity of cationic poly(glcoamidoamine) (PGAA)-pDNA complexes, quartz crystal microbalance was employed to measure the mass of GAGs that associated with a polyplex monolayer. Affinity of six different GAGs that varied in the charge density were measured for polyplexes formed with poly(galactaramidopentaethylenetetramine) (G4) cationic polymers and pDNA. Results showed that the affinity of GAGs for G4 polyplexes was not completely dependent on the electrostatic interactions indicating that other factors contribute to the GAG-polyplex interactions. The results provided some insight into the interactions of polyplexes with cell surface GAGs and the role they play in cellular internalization. Two adamantane terminated polymers were investigated to study the non-covalent inclusion complexation with click cluster non-viral nucleic acid delivery vehicles for passive targeting of the click cluster-pDNA complexes (polyplex). Incorporation of adamantyl terminated poly(ethylene glycol) (Ad-PEG) and poly(2-deoxy-2-methacrylamido glucopyranose) (Ad-pMAG) polymers into the polyplex formulation revealed increased colloidal stability under physiological salt concentrations. Ad-pMAG polyplexes resulted in lower cellular uptake for HeLa cells and not two glioblastoma cell lines indicating the pMAG corona imparts some cell line specificity to the polyplexes. Ad-pMAG provided favorable biological properties when incorporated into the polyplexes as well as increased polyplex physical properties. / Ph. D. poly(amide) oxamide segmented copolymer trioxamide poly(urea) poly(urea oxamide) non-viral gene delivery click cluster
47	Étude de l'élaboration de nano-particules élastomères et application de celles-ci en tant qu'agents renforçants pour le poly(acide lactique) / Study of the development of elastomer nanoparticles and their application as reinforcing agents for poly(lactic acid) Fang, Yuan 07 December 2012 (has links) Le poly (acide lactique) (PLA), est un polymère synthétisé à partir de ressources renouvelables, qui est l'objet de beaucoup d'études à l'heure actuelle mais qui souffre d'une faible résistance au choc. Le but de ce travail est de rechercher des pistes permettant la préparation d'un matériau à base de PLA avec une résistance au choc améliorée tout en minimisant la perte de résistance à la traction. Les travaux présentés ici ont étudié le rôle de nanoparticules élastomères de poly (acrylate de butyle) (PBA) chargées de laponite (LRD) (PBA-LRD) ainsi que de nanocomposites coeur-écorce (PBA-LRD)/poly(méthacrylate de méthyle) (PMMA) en tant qu'agents de renforcement d'une matrice de PLA. Ces nanoparticules ont été dispersées dans la matrice PLA à l'état fondu. La synthèse de ces nanoparticules a été effectuée par polymérisation en émulsion ou miniémulsion. La laponite a été incorporée dans les nanoparticules afin de minimiser la perte de la rigidité tout en améliorant la résistance au choc de PLA. Trois types de tensioactifs et des modifications de surface de la laponite ont été testées pour améliorer l'adhérence entre les particules de PBA et la matrice de PLA. Enfin une écorce de PMMA a été utilisée pour assurer la bonne adhérence entre les particules de PBA et de matrice PLA. Nous avons montré que les particules coeur-écorce ont permis d'augmenter la résistance au choc au 3 fois du PLA tout en réduisant la diminution du module d'Young et la perte de résistance à la traction (~25%). Les propriétés de les particules synthétiques et les propriétés des mélange du PLA avec les particules PBA ou particules coeur-écorce ont été étudiées par diverses techniques de caractérisation (DLS, FTIR, ATG, MET, MEB, RMN 1H, DSC, DMTA...) / Poly (lactic acid) (PLA), come from renewable resources, one of the most important biopolymers, suffers from weak impact resistance. The aim of this work is to develop a process that will allow preparing a PLA with improved impact resistance while minimizing loss in tensile strength. The work presented here examined in detail the synthesis of poly(butyl acrylate) (PBA) nanoparticles charged with laponite (LRD) (PBA-LRD) and (PBA-LRD) / poly(methyl methacrylate) (PMMA) core-shell nanocomposites. They were dispersed phase in PLA matrix and were synthesized by emulsion or miniemulsion polymerization. The clay such as laponite was included in these nanoparticles to minimize the loss of rigidity while improving the impact resistance of PLA. Note that three types of surfactants and some modify agents for LRD have been tried to improve the adhesion between the PBA particles and matrix PLA, PMMA was finally used to ensure a good adhesion between the PBA particles and the matrix. To this end, we explored successively the PLA blend, using PBA nanocomposites and the PBA/PMMA core-shell nanoparticles as reinforcing agents, with improved impact resistance, showing that core-shell particles allowed increasing of 3 times of impact strength of the PLA with a minimum amount of loss (~25%) in Young?s modulus and tensile strength. The properties of the synthetic particles and the properties of PLA blends have been demonstrated by various characterization techniques (DLS, FTIR, TGA, TEM, SEM, 1H-NMR, DSC, DMTA ...) Poly (acide lactique) Laponite Polymérisation en mini-émulsion Poly (méthacrylate de méthyle) Nanoparticules coeur-écorce Poly(lactic acid) Laponite Poly(butyl acrylate) Mechanical properties Miniemulsion polymerization Poly(methyl methacrylate) Core-shell nanoparticles 620.192 668.9
48	Synthèse et étude physico-chimique de copolymères amphiphiles à base de poly(2-méthyl-2-oxazoline) / Synthesis and physical chemistry study of amphiphilic copolymers based on poly(2-methyl-2-oxazoline) Guillerm, Brieuc 16 December 2011 (has links) Ce travail de thèse décrit l'élaboration de copolymères amphiphiles obtenus par couplage de deux homopolymères. La synthèse des copolymères s'est effectuée en deux étapes. Dans un premier temps, des homopolymères de type poly(2-méthyl-2-oxazoline) (P(MOx)) et poly(acrylate de tert-butyle) (P(At-Bu)) ont été préparés par polymérisation par ouverture de cycle cationique (CROP) et par polymérisation radicalaire contrôlée de type RAFT ou ATRP, respectivement. Puis les copolymères amphiphiles diblocs ont finalement été obtenus par une réaction de couplage polymère-polymère de type cycloaddition de Huisgen. Une étude physico-chimique de ces copolymères dans l'eau a mis en évidence la présence d'agrégats qui présentent une morphologie sphérique, des tailles inférieures à 100 nm et des concentrations d'agrégation critique de l'ordre de 10-6 mol.L-1.Les connaissances acquises sur la synthèse et l'étude des copolymères à blocs amphiphiles ont également permis le développement de copolymères greffés amphiphiles poly(-caprolactone)-g-poly(2-méthyl-2-oxazoline) (PCL-g-P(MOx)), constitués d'un bloc hydrophobe PCL sur lequel des chaînes hydrophiles P(MOx) ont été greffées. L'étude du comportement de ces copolymères dans l'eau montre la formation d'agrégats avec des caractéristiques proches de celles obtenues pour les copolymères diblocs amphiphiles. Un autre point intéressant est que la P(MOx) permet de solubiliser la PCL dans l'eau.Ces deux études illustrent l'apport de la chimie macromoléculaire pour la préparation de structures amphiphiles parfaitement définies qui s'organisent en phase aqueuse en agrégats. Ces derniers pourraient notamment être utilisés dans le domaine biomédical. / This manuscript deals with the synthesis of amphiphilic diblock copolymers obtained by the coupling of both hydrophobic and hydrophilic homopolymers. The copolymers were achieved in two steps. On the one hand, homopolymers poly(2-methyl-2-oxazoline) P(MOx)s and poly(tert-butyl acrylate)s (P(At-Bu) were synthesized by cationic ring opening polymerization (CROP) and by Reversible Addition-Fragmentation Transfer (RAFT) polymerization and atom transfer radical polymerization (ATRP), respectively. Finally, amphiphilic diblock copolymers were achieved by Huisgen's cycloaddition. Physical chemistry studies in water proved the formation of aggregates. The latter had a spherical morphology, sizes below 100 nm and critical aggregation concentration around 10-6 mol.L-1.Knowledge acquired on the synthesis and the study of amphiphilic block copolymers led to the development of poly(-caprolactone)-g-poly(2-methyl-2-oxazoline) (PCL-g-P(MOx)) amphiphilic graft copolymers, made of a hydrophobic PCL grafted with hydrophilic P(MOx) moieties. The study of aqueous solution of such copolymers showed the formation of aggregates with characteristics close from those obtained for the diblock copolymers. Another interesting point is that P(MOx) permitted the solubilization of PCL in water.The reported work illustrated the importance of macromolecular chemistry for the obtaining of amphiphilic copolymers with controlled molecular weight and narrow molar mass distributions which self-assemble in water. Such kind of materials could be used in the biomedical field. Copolymères amphiphiles Poly(2-méthyl-2-oxazoline) Couplage polymère-polymère Chimie « click » Poly(acrylate de t-butyle)) Poly(e-caprolactone) Amphiphilic copolymers Poly(2-methyl-2-oxazoline) Polymer-polymer coupling Click chemistry Poly(t-butyl acrylate) Poly(e-caprolactone)
49	Synthèse d'agents RAFT macromoléculaires hydrophiles à base d'acide (méth)acrylique ou d'alginate pour l'élaboration de nanoparticules par polymérisation en émulsion / Synthesis of poly(meth)acrylic acid and alginate-based hydrophilic macromolecular RAFT agents for the design of nanoparticles by emulsion polymerization Chaduc, Isabelle 31 October 2013 (has links) Ces travaux décrivent la synthèse de nanoparticules stabilisées par des polyélectrolytes d’originesynthétique (poly(acide (méth)acrylique)) ou naturelle (alginate) par polymérisation radicalairecontrôlée (PRC) de type RAFT en émulsion. Ce procédé est basé sur l’utilisation d’un polymèrehydrophile obtenu par RAFT (macroRAFT) qui est réactivé dans l’eau pour la polymérisation d’unmonomère hydrophobe. Des copolymères à blocs amphiphiles sont ainsi générés et s’auto-assemblent in situ pour former des nanoparticules. Dans un premier temps, nous avons cherché à conduire l’ensemble du procédé en milieu aqueux. Des études ont ainsi été menées sur la polymérisation RAFTdans l’eau de l’acide acrylique et de l’acide méthacrylique. Des homopolymères bien définis ont été obtenus sur une large gamme de conditions, puis ont été utilisés comme macroRAFTs pour la polymérisation en émulsion de monomères hydrophobes. Des nanoparticules stables constituées de copolymères à blocs amphiphiles bien définis ont été produites. Il a été montré que le contrôle de la polymérisation et la nucléation dépendaient fortement du pH, mais qu’une bonne stabilité colloïdale était néanmoins observée dans tous les cas. Ce procédé "one-pot " a ensuite été extrapolé à la synthèse de particules stabilisées par des copolymères hydrophiles de N-acryloylmorpholine (NAM) et de macromonomères d’alginate. Des nano-objets aux morphologies variées ont été obtenus. Afin de mieux appréhender la formation de ces morphologies, un système modèle employant un copolymère hydrophile de NAM et de macromonomère de polyNAM obtenu par polymérisation RAFT a été étudiépour la polymérisation en émulsion du styrène. / This work describes the synthesis of nanoparticles stabilized by polyelectrolytes from synthetic(poly((meth)acrylic acid)) or natural (alginate) source by controlled free radical polymerization (CRP),namely RAFT, in emulsion. This process is based on the use of a hydrophilic polymer prepared by RAFT (i.e. macroRAFT) which is reactivated in water for the polymerization of a hydrophobic monomer. The formation of amphiphilic block copolymers which self-assemble in situ leads to the formation of nanoparticles. Firstly, we tried to perform the whole process in water. The RAFT polymerization of acrylic acid and methacrylic acid was studied in this context. Well-defined homopolymers were obtained under a large range of conditions, and further used as macroRAFTs in emulsion polymerization of hydrophobic monomers. Stable nanoparticles composed of well-defined amphiphilic block copolymers were produced. It was shown that the control of the polymerization and the nucleation were strongly dependent on the pH. Nevertheless, a good colloidal stability wasobserved in all cases. This “one-pot” process was then extrapolated to the synthesis of particles stabilized by hydrophilic copolymers of N-acryloylmorpholine (NAM) and alginate macromonomer. Nano-objects with various morphologies were obtained. In order to better understand the formation of these morphologies, a model system using a hydrophilic copolymer of NAM and a polyNAM macromonomer obtained by RAFT polymerization was studied in styrene emulsion polymerization. RAFT Émulsion Poly(acide méthacrylique) Poly(acide acrylique) Alginate Poly(N-acryloylmorpholine) Polyélectrolytes Copolymères à blocs amphiphiles Nanoparticule RAFT Emulsion Poly(methacrylic acid) Poly(acrylic acid) Alginate Poly(N-acryloylmorpholine) Polyelectrolytes Amphiphilic block copolymers Nanoparticle 547.7
50	Synthesis of poly(3,4-ethylenedioxythiohene), polyaniline and their metal-composite nano-objects by dispersion polymerization Mumtaz, Muhammad 26 October 2009 (has links) Dans l'objectif d'améliorer la mise en forme des polymères semi-conducteurs tels que le poly (3,4-éthylènedioxythiophène) et la polyaniline, nous avons développé leur synthèse par polymérisation en dispersion de leurs monomères respectifs en utilisant le poly(oxyde d'éthylène), le poly (vinyl alcool), le poly [(N-vinylpyrrolidone)-co-(vinyl alcool)] et le poly [(N-vinylpyrrolidone)-b-(vinyl alcool)] comme stabilisants réactifs dans des milieux dispersants aqueux. Des nano-objets de nature et de structure bien définis ont été obtenus. Afin de moduler la conductivité et les propriétés opto-électroniques de ces nano-objets, leurs composites avec des métaux tels que l'or, l'argent et le cuivre ont été préparés en utilisant les sels métalliques correspondants comme co-oxydants au cours de la polymérisation en dispersion. La morphologie des nano-objets a notamment été évaluée par Microscopie Electronique en Transmission, Microscopie Electronique à Balayage, et Microscopie à Force Atomique. Le nature cœur-écorce de ces nano-objets, le niveau de dopage et la présence de métaux dans les nano-composites ont été examinés par spectrométrie de photoélectrons induits par rayons X. / With the objective to improve the processability of “stiff” semi-conducting polymers, well defined poly(3,4-ethylenedioxythiophene) and polyaniline core-shell nano-objects were synthesized by dispersion polymerization of their respective monomers using poly(ethylene oxide), poly(vinyl alcohol), poly[(N-vinylpyrrolidone)-co-(vinyl alcohol)] and poly[(N-vinylpyrrolidone)-b-(vinyl alcohol)]-based reactive stabilizers in aqueous dispersant media. In order to improve the conductivity and opto-electronic properties of these nano-objects, their composite with gold, silver and copper were prepared using the metal salts as co-oxidants during dispersion polymerization. The morphology of the nano-objects was observed by microscopy analyses such as Transmission Electron Microscopy, Scanning Electron Microscopy, and Atomic Force Microscopy. The core-shell nature of these nano-objects, doping level and the presence of metals in the nano-composites were examined by X-rays Photoelectron Spectroscopy. Poly (3,4-éthylènedioxythiophène) Polymérisation en milieu dispersé Stabilisants polymères réactifs Poly (oxyde d'éthylène) Poly (vinyl alcool) Nanocomposites de PEDOT

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