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41	Mise au point de micelles polyioniques pour l'administration de biomacromolécules thérapeutiques : synthèse de polymères et études physicochimiques Dufresne, Marie-Hélène January 2008 (has links) Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal. Vectorisation Drug delivery Ciblage Targeting Micelles polyioniques Polyion complex micelles Biomacromolécules Biomacromolecules Héparine Heparin Oligonucléotides antisens Antisense oligonucleotide Polymères cationiques Cationic copolymers Atom transfer radical polymerization
42	Micelles polymères unimoléculaires ou inverses pour l'administration orale d'agent thérapeutiques Jones, Marie-Christine January 2007 (has links) Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal. Micelles polymères Polymeric micelles Micelles inverses Reverse micelles Micelles unimoléculaires Unimolecular micelles Voie orale Peptide Peptide Vasopressine Vasopressin Atom transfer radical polymerization Sensibilité au pH pH-sensistivity
43	Couplage ROMP et ATRP en milieu dispersé aqueux : préparation et étude morphologique de particules polymères composites Airaud, Cédric 16 December 2008 (has links) Le confinement de polymères incompatibles au sein de particules induit une séparation de phase et conduit à la formation de morphologies particulières (cœur-écorce, hémisphérique…). Cette nanostructuration est à l’origine de propriétés de filmification particulières qui justifient l’utilisation des particules polymères composites dans le cadre d’applications comme la formulation de peintures ou de revêtements. Ce travail s’intéresse au développement d’approches permettant de préparer ces particules polymères composites en une seule étape et en milieu aqueux. La stratégie proposée repose sur le couplage « en simultané » de deux polymérisations distinctes: la polymérisation de cyclooléfines par métathèse (ROMP) et la polymérisation radicalaire par transfert d’atome (ATRP). Après avoir mis en évidence les difficultés liées au couplage de la ROMP et de l’ATRP en milieu dispersé aqueux, deux approches originales faisant intervenir respectivement des conditions de miniémulsion et de microémulsion sont proposées. Pour chacune d’elles, la présentation du principe de la synthèse et l’analyse de ses résultats précèdent l’étude morphologique des particules produites. / So as to broaden the scope of their applications in paints, coatings and impact-resistant plastics, many investigations have been dedicated to the preparation of nanostructured colloids over the past decades. Original morphologies including core-shell, hemispherical and complex occluded structures (raspberry-like, golf ball-like, octopus-like) can now be readily prepared. This work proposes a new straightforward one-pot, one-step, one-catalyst strategy to prepare polymer composite particles based on the simultaneous combination of two mechanistically distinct polymerizations in aqueous dispersed media. Norbornene (NB) and methyl methacrylate (MMA) were converted via Ring-Opening Metathesis Polymerization (ROMP) and Atom-Transfer Radical Polymerization (ATRP), respectively. Two original routes, designed to ensure simultaneous ROMP and ATRP, respectively under mini- and microemulsion conditions, are proposed. Both are successively reviewed on chemical and colloidal levels. Specific attention is paid to the morphologies of the prepared particles. Polymérisation par métathèse ROMP ATRP Particules polymères composites Milieu dispersé Miniémulsion Microémulsion Ring-opening Metathesis polymerization ROMP Atom-transfer radical polymerization ATRP Polymer composite particles Dispersed media Miniemulsion Microemulsion
44	Élaboration contrôlée de glycopolymères amphiphiles à partir de polysaccharide : synthèse de Dextrane-g-PMMA par polymérisation radicalaire par transfert d'atome / Controlled elaboration of amphiphilics glycopolymers from polysaccharides : synthesis of dextran-G-PMMA by atom transfer radical polymerization Dupayage, Ludovic 03 February 2009 (has links) De nouveaux glycopolymères amphiphiles en peigne de type dextrane-g-poly(méthacrylate de méthyle) ont été obtenus via une polymérisation radicalaire contrôlée par transfert d’atome (ATRP). Pour contrôler les paramètres macromoléculaires de ces glycopolymères potentiellement biocompatibles et en partie biodégradables, la stratégie de synthèse « grafting from » a été sélectionnée et appliquée selon deux voies de synthèse. La première voie comporte quatre étapes : acétylation partielle des fonctions hydroxyle du dextrane ; introduction des groupements amorceurs d’ATRP ; ATRP contrôlée du méthacrylate de méthyle dans le diméthylsulfoxyde ; hydrolyse des groupements acétate dans des conditions douces. La seconde voie de synthèse permet d’obtenir ces glycopolymères en seulement deux étapes : introduction directe des groupements amorceurs d’ATRP sur le dextrane ; ATRP contrôlée du méthacrylate de méthyle dans le diméthylsulfoxyde. Des études détaillées de chaque étape ont permis à la fois d’estimer la longueur de la chaîne de dextrane et d’assurer le contrôle de l’architecture des glycopolymères (nombre et longueur des greffons). Des études préliminaires par tensiométrie interfaciale ont permit d’évaluer le caractère tensioactif de ces glycopolymères / Synthesis of the new comb-like amphiphilic glycopolymer dextran-g-poly(methyl methacrylate) was obtained thanks to an Atom Transfert Radical Polymerization (ATRP). In order to control the macromolecular parameters of these biocompatible and partly biodegradable glycopolymers, the “grafting from” strategy was applied using two different multi-step pathways. The first one is composed of four steps: partial acetylation of dextran hydroxyl groups; introduction of initiator groups convenient for ATRP; ATRP of methyl methacrylate in dimethylsulfoxide; acetyl group deprotection under mild conditions. The second pathway allows us to obtain such glycopolymers in only two steps: direct introduction of the same initiator groups onto the dextran chain and subsequent ATRP of methyl methacrylate in dimethylsulfoxide. Throughout the synthesis, detailed studies of each step enabled us to estimate the length of the dextran backbone and to assure the control of copolymer architecture in terms of graft number and graft length. Preliminary interfacial tension measurements highlighted the surfactant properties of such glycopolymers Dextrane Tensioactif Biocompatible Amphiphile Grafting from Copolymère en peigne Poly(méthacrylate de méthyle) (PMMA) Polysaccharide Dextran Biocompatible Amphiphilic Grafting from Polysaccharide Poly(methylmethacrylate) (PMMA) Comb-like copolymers Surfactant.
45	Polymer Nanocomposites in Thin Film Applications Fogelström, Linda January 2010 (has links) The introduction of a nanoscopic reinforcing phase to a polymer matrix offers great possibilities of obtaining improved properties, enabling applications outside the boundaries of traditional composites. The majority of the work in this thesis has been devoted to polymer/clay nanocomposites in coating applications, using the hydroxyl-functional hyperbranched polyester Boltorn® as matrix and montmorillonite clay as nanofiller. Nanocomposites with a high degree of exfoliation were readily prepared using the straightforward solution-intercalation method with water as solvent. Hard and scratch-resistant coatings with preserved flexibility and transparency were obtained, and acrylate functionalization of Boltorn® rendered a UV-curable system with similar property improvements. In order to elucidate the effect of the dendritic architecture on the exfoliation process, a comparative study on the hyperbranched polyester Boltorn® and a linear analogue of this polymer was performed. X-ray diffraction and transmission electron microscopy confirmed the superior efficiency of the hyperbranched polymer in the preparation of this type of nanocomposites. Additionally, an objective of this thesis was to investigate how cellulose nanofibers can be utilized in high performance polymer nanocomposites. A reactive cellulose “nanopaper” template was combined with a hydrophilic hyperbranched thermoset matrix, resulting in a unique nanocomposite with significantly enhanced properties. Moreover, in order to fully utilize the great potential of cellulose nanofibers as reinforcement in hydrophobic polymer matrices, the hydrophilic surface of cellulose needs to be modified in order to improve the compatibility. For this, a grafting-from approach was explored, using ring-opening polymerization of ε-caprolactone (CL) from microfibrillated cellulose (MFC), resulting in PCL-modified MFC. It was found that the hydrophobicity of the cellulose surfaces increased with longer graft lengths, and that polymer grafting rendered a smoother surface morphology. Subsequently, PCL-grafted MFC film/PCL film bilayer laminates were prepared in order to investigate the interfacial adhesion. Peel tests demonstrated a gradual increase in the interfacial adhesion with increasing graft lengths. / QC20100621 Nanocomposites hyperbranched polymers montmorillonite clay nanoparticles exfoliated coatings crosslinking TEM XRD mechanical properties thermal properties cellulose nanofibers Atom Transfer Radical Polymerization Ring-Opening Polymerization poly(ε-caprolactone) surface modification grafting interfacial adhesion Polymer chemistry Polymerkemi
46	Kinetics and Mechanism of Cu-Catalyzed Atom Transfer Radical Polymerization Sörensen, Nicolai 26 May 2015 (has links) No description available. 540 copper deactivation termination chain-length dependence electron paramagnetic resonance (EPR) kinetics spectroscopy pulsed-laser polymerization (PLP) Chemie (PPN62138352X)
47	Kinetik von Atom-Transfer Radikalischen Polymerisationen bis zu hohen Drücken / Kinetics of Atom-Transfer Radical Polymerization up to High Pressure Morick, Joachim 26 September 2012 (has links) No description available. 540 Chemie SW 000 SGC 000 Chemistry ATRP Kinetik Methylmethacrylat Styrol Butylacrylat Atom-Transfer Radical Polymerization ATRP kinetics methyl methacrylate styrene butyl acrylate 35.13 35.80
48	Mise au point de micelles polyioniques pour l'administration de biomacromolécules thérapeutiques : synthèse de polymères et études physicochimiques Dufresne, Marie-Hélène January 2008 (has links) Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal Vectorisation Drug delivery Ciblage Targeting Micelles polyioniques Polyion complex micelles Biomacromolécules Biomacromolecules Héparine Heparin Oligonucléotides antisens Antisense oligonucleotide Polymères cationiques Cationic copolymers Atom transfer radical polymerization
49	Micelles polymères unimoléculaires ou inverses pour l'administration orale d'agent thérapeutiques Jones, Marie-Christine January 2007 (has links) Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal Micelles polymères Polymeric micelles Micelles inverses Reverse micelles Micelles unimoléculaires Unimolecular micelles Voie orale Peptide Peptide Vasopressine Vasopressin Atom transfer radical polymerization Sensibilité au pH pH-sensistivity
50	DEVELOPMENT OF NOVEL MULTI-RESPONSIVE MATERIALS CHARACTERIZED BY POTENTIAL CONTROLLED RELEASE PROPERTIES Chikh Alard, Ibaa 05 December 2018 (has links) (PDF) With the emergence of novel and more effective drug therapies, increased importance is being placed upon the methods by which these drugs are being delivered to the body. In conventional drug delivery systems, there is very little control over the release of drug. The effective concentration at the target site can be achieved by intermittent administration of grossly excessive doses, which, often results in constantly, unpredictable variations in plasma concentrations, with the risk of reaching levels below or above the therapeutic range leading to marked side effects. A plethora of formulation strategies mainly based on polymeric/lipid nanoparticles, are described in literature. Even though these systems are therapeutically advantageous in comparison to conventional systems, they remain insensitive to the changing metabolic states of the body although the symptoms of most metabolic diseases follow a rhythmic pattern.A more appropriate and effective approach of managing some of these conditions lies in the chronotherapy. This approach allows for pulsed or self-regulated drug delivery which is adjusted to the staging of biological rhythms, since the onset of certain diseases exhibits strong circadian temporal dependence. In order to reach the objective of mimicking the biophysical and biochemical processes of pathological states, many innovations in material design for drug delivery systems (DDS) that are able to release the therapeutic payload-on-demand were done to release the therapeutic agent only when it is required, according to the physiological need. The development of multidisciplinary research teams has brought huge advantages in the design, fabrication and utilization of such smart systems, especially in the pharmaceutical field. Interestingly, numerous smart polymeric materials exhibit a response to a specific stimulus. A step further, the elaboration of purpose-built monomers can give rise to compounds with tunable sensitivities or multi-stimuli responsiveness. These smart polymers demonstrate an active responsiveness to environmental (or external) signals and change their physicochemical properties as designed (e.g. conformation, solubility, shape, charge or size). As far as the stimuli are concerned, they consist of physical (e.g. temperature, ultrasound, light, electricity, magnetic or mechanical stress), chemical (e.g. pH, ionic strength) and biological signals (e.g. enzymes, biomolecules). Due to the intrapersonal variabilities which may make internal stimuli hazardous, externally controlled systems rely on externally applied stimuli that are produced by stimuli-generating devices, which results in pulsed drug delivery. This type of delivery may be rapid and allows a transient release of a determined amount of drug within a short period of time immediately after a pre-determined off-release period. A novel strategy for the formation of multi-stimuli responsive materials endowed with pH, magnetic and light sensitivity was achieved. The approach relied on the incorporation of magnetic tetrahalogenoferrate(III) anions along a polymeric backbone based on poly(2-(N,N-dimethylamino) ethyl meth-acrylate) (PDMAEMA). Starting from the same PDMAEMA, quaternized pending amine groups with various halide derivatives gave rise to magnetic materials after anion metathesis. Measuring the magnetic susceptibility of these materials exhibited that the magnetic susceptibility increased as the substituted group size decreased (become smaller) which was apparently related to the steric hindrance around the ionic pendants. Additionally, a good correlation between the magnetic susceptibility and ferric content was found. Additional experimental and theoretical Raman analyses allowed the determination of the nature of the magnetic species constituting the materials. This strategy further oﬀers the opportunity to tailor the magnetic response through partial ammonium salt formation. In order to merge the magnetic properties of ferric-based materials with another stimuli-responsive functionality, random copolymers containing DMAEMA (D) with diazobenzene (A) unit were prepared. So, three copolymers PDA were synthesized (with targeted D/A ratios 4/6 (PDA4), 6/4 (PDA6) and 8/2 (PDA8)). Meanwhile, diﬀerent degrees of amine quaternization (10, 50 and 100 %) were applied, which led to the following polymeric salts PDAX/Y where X = 4, 6, 8 (referring to the percentage of the DMAEMA unit) and Y = 10, 50 and 100 (referring to the percentage of quaternized amine groups). Finally, the aforementioned materials were converted into magnetic polymers by anion exchange. As a result, magnetic responses correlated well with amount of iron oxide in these compounds and the amount of ionic pending groups along the backbone. Moreover, the remaining tertiary amines conferred pH sensitivity to the polymers whereas the diazobenzene units ensured light responsiveness through the well-established trans-to-cis isomerization.In order to functionalize these materials in the pharmaceutical field, an intelligent delivery system was prepared. Firstly, an attempt to formulate riboflavin-5’-phosphate sodium (RPS) loaded on PDA8 microspheres was made using double emulsion evaporation method. Meanwhile, prednisolone (PRD) microspheres were prepared using s/o/w emulsion technique. Subsequently, coating systems of cochineal red tablets were developed. These tablets were coated with polymer solution (using each of three types of copolymers: PDA8, PDA6, and PDA4) until the desired percentage of the coating was achieved (10, 15, and 20 % w/w). The cumulative release profiles of cochineal red tablets coated with PDA8, PDA6, and PDA4 showed a pH-sensitive release behavior. The release in the neutral media (pH ≈ 7.0) was very slow (less than 3 % after one hour). Then, after changing the pH to 1.2, an increase in the release of cochineal was observed. Furthermore, the cumulative release of cochineal red was at the highest value for the PDA8 and the lowest for PDA4 depending on the percentage of PDMAEMA moieties. Moreover, by increasing the percentage of the coating from (10, 15 to 20 % w/w), the cumulative release of cochineal decreased. Therefore, the copolymer PDAX can be used for controlling the release of drug by changing the pH value.Finally, the cochineal tablets coated with PDA6 (10 %) showed features of light sensitivity. The release of cochineal red from coated tablets was only due to the switching in the conformational trans/cis isomerization of azobenzene moieties upon irradiation, which was confirmed by comparing the release of coated tablets with uncoated tablets upon irradiation. / Doctorat en Sciences biomédicales et pharmaceutiques (Pharmacie) / info:eu-repo/semantics/nonPublished Pharmacie galénique Biochimie pharmaceutique Chimie macromoléculaire Chimie organique Stimuli-responsive materials Drug delivery systems azobenzene pH-responsive polymers Photo-responsive polymers Magnetic responsive polymers

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