Global ETD Search

411	Etude de la Poly(ADP-ribosyl)ation dans un contexte des cassures double-brins des ADN nucléaire et mitochondriaux chez Drosophila melanogaster / Study of Poly(ADP-ribosyl)ation in response to mitochondrial and nuclear DNA strand breaks, in Drosophila melanogaster model Ishak, Layal 30 March 2016 (has links) L’ADN cellulaire qu’il soit nucléaire ou mitochondrial est constamment soumis à l’action de stress d’origine exogène ou même endogène à la base d’altérations plus ou moins profondes de sa structure. Ces modifications chimiques sont très variées et peuvent aller de l’oxydation d’une base aux cassures double-brins de la molécule d’ADN. Ces dernières sont considérées comme les dommages les plus agressifs pour la cellule car peuvent conduire à la perte d’information et donc à la mort cellulaire. Parmi les systèmes de surveillance de la stabilité du génome figure la Poly(ADP-ribosyl)ation (PARylation). Cette modification post-traductionnelle est assurée essentiellement par les protéines PARP et PARG et est caractérisée par l’incorporation des polymères d’ADP ribose (pADPr) sur des protéines cibles. La PARylation constitue un élément clé dans plusieurs voies de maintien de l’intégrité génomique (BER, NHEJ, HR). La PARylation est aussi décrite au niveau de la mitochondrie mais son rôle dans la gestion des DSBs de l’ADNmt n’est pas connu. Le travail, objet de cette thèse, consiste à étudier le rôle de la PARylation dans le cas des DSB au niveau général chez la drosophile et ensuite de comprendre les mécanismes de gestion des DSB mitochondriales et évaluer l’implication de la PARylation dans ce processus. Nos résultats montrent que : (1) le comportement de la PARylation ne varie pas au cours du processus de cassures et de réparation de l’ADN nucléaire, alors que l’expression des ARNm de PARP-I et PARP-II augmente durant la phase de réparation ; (2) les cassures de l’ADN mitochondrial, induites par la bléomycine, entraînent une augmentation du nombre de copies de l’ADNmt. Cette augmentation transitoire de la quantité de l’ADNmt est observée durant la phase des dommages et retourne à la valeur initiale durant la phase de la réparation. Ce comportement semble être régulé par PARP. L’ensemble de ces résultats suggère que la réparation des DSBs est indépendante de la PARylation au niveau nucléaire mais que la présence de PARP est importante. De plus, PARP semble avoir un rôle dans la régulation de la réplication de l’ADNmt en réponse à un stress génotoxique. / Both nuclear and mitochondrial DNA alterationsarise following exposure to environmental and endogenous stresses. These genomic alterations are various, ranging from base oxidation to DNA strand breaks, single- and double-strand breaks. These damages are highly detrimental to the cell because they can lead to loss of genetic information and thus to cell death. However, cells have developed various mechanisms to counteract this biological issue and to lead up to a complex DNA damage response (DDR). The Poly (ADP- ribosyl) ation (PARylation) is among these DDR systems. This post-translational modification is mainly carried out by PARP and PARG proteins and is characterized by the incorporation of polymers of ADP-ribose on target proteins. The majority of the PARylationfunctions are related to cellular stress response, particulary in response to genomic damages where it is implicated in many DNA integrity pathways such as Base Excision Repair, Non Homologous End Joining and Homologous Recombination. In contrast to the nucleus, PARylation is also described in the mitochondria but its role in mtDNA integrityis still a heavily debate issue, particularly in case of mtDNA DSBs.To understand it, we used Drosophila model wherePARP-B isoform (human PARP-1 ortholog) is the only enzymatically active form in Drosophila PARP family. The aim of this thesis is to study the role of PARylation in response to DSBs induction in nucleus and mitochondrial DNAand then to understand the mechanisms involved in mtDNA integrity and to evaluate the role of PARylation in this process. Our results show that PARylation level remains stable during DSBs induction and also during repair process,contrary to what is shown in Human cells.However, PARP-I and PARP-II mRNA expression increase during repair period. In mitochondria compartment,our data show an increase of mtDNA copy number in presence of mtDNA DSBs. This increased level returns to normal during repair period and seems to be dependent on PARP. All these results suggest that DSBs repair is PARylation independent at the nuclear level but that the presence of PARP is important. In addition, PARP appears to have a role in the regulation of mtDNA replication in response to genotoxic stress. Poly(ADP-ribosyl)ation (PARylation) PARP PARG ADN ADNmt DSBs Poly(ADP-ribosyl)ation PARP PARG DNA ADNmt DSBs
412	Synthèse, caractérisation et intérêt biomédical de (glyco)copolymères amphiphiles, <br />biocompatibles et bioéliminables, de différentes architectures Jutta, Rieger 28 April 2006 (has links) (PDF) Ce travail a pour objectif principal la modification de la surface de nanoparticules de polymères par de nouveaux copolymères amphiphiles et biocompatibles, possédant différentes architectures. Les copolymères considérés dans cette étude sont composés d'une chaine hydrophile de poly(oxyde d'éthylène) (POE) et d'une chaîne hydrophobe à base de poly(ε-caprolactone) (PCL).<br />A partir d'un POE coiffé par une unité ε-caprolactone et par un groupement méthoxy à ses extrémités α et ω, respectivement, (γPOE.CL), des copolymères amphiphiles greffés, PCL-g-POE, et un copolymère ternaire possédant une architecture en étoile ont été synthétisés. Des copolymères diblocs, POE-b-PCL, ont également été préparés. <br />Les copolymères diblocs et greffés de POE et PCL, tensioactifs, ont été utilisés pour stabiliser et modifier la surface de nanoparticles polymères (NP), vecteurs potentiels pour la délivrance de principes actifs. L'effet des propriétés des copolymères (architecture, composition et quantité) sur la formation et la structure des nanoparticules, a été examiné. De plus, l'activation du complément, c.-à.-d. la furtivité des nanoparticules, en fonction de la composition et de l'architecture du copolymère utilisé a été étudiée.<br />Un autre défi relevé dans ce travail est la fonctionnalisation de la surface de nanoparticules pas des motifs mannose afin de cibler des cellules dendritiques. A cet effet, des dérivés du mannose ont été fixés de manière covalente à l'extrémité de la poly(ε-caprolactone) et de copolymères diblocs POE-b-PCL. Ces derniers ont été utilisés avec succès pour modifier la surface de nanoparticules de polylactide. [CHIM:OTHE] Chemical Sciences/Other nanoparticules de polymères glycopolymères poly(oxyde d'éthylène) poly(ε-caprolactone) polylactide furtivité mannose
413	Stimuli-responsive Novel Amphiphilic Polymers for Chemical and Biomedical Applications Tam, K. C., Ravi, P., Dai, S., Tan, C. H. 01 1900 (has links) Amphiphilic polymers are a class of polymers that self-assemble into different types of microstructure, depending on the solvent environment and external stimuli. Self assembly structures can exist in many different forms, such as spherical micelles, rod-like micelles, bi-layers, vesicles, bi-continuous structure etc. Most biological systems are basically comprised of many of these organised structures arranged in an intelligent manner, which impart functions and life to the system. We have adopted the atom transfer radical polymerization (ATRP) technique to synthesize various types of block copolymer systems that self-assemble into different microstructure when subject to an external stimuli, such as pH or temperature. The systems that we have studied are: (1) pH responsive fullerene (C60) containing poly(methacrylic acid) (PMAA-b-C60); (2) pH and temperature responsive fullerene containing poly[2-(dimethylamino)ethyl methacrylate] (C₆₀-b-PDMAEMA); (3) other responsive water-soluble fullerene systems. By varying temperature, pH and salt concentration, different types microstructure can be produced. In the presence of inorganic salts, fractal patterns at nano- to microscopic dimension were observed for negatively charged PMAA-b-C60, while such structure was not observed for positively charged PDMAEMA-b-C60. We demonstrated that negatively charged fullerene containing polymeric systems can serve as excellent nano-templates for the controlled growth of inorganic crystals at the nano- to micrometer length scale and the possible mechanism was proposed. The physical properties and the characteristics of their self-assembly properties will be discussed, and their implications to chemical and biomedical applications will be highlighted. / Singapore-MIT Alliance (SMA) Amphiphilic polymers self-assembly microstructures atom transfer radical polymerization ATRP fullerene poly(methacrilic acid)
414	Synthese monodisperser, multifunktionaler Poly(amidoamine) und ihre Anwendung als nicht-virale Vektoren für die Gentherapie / Synthesis of monodisperse, multifunctional poly(amidoamines) and their application as non-viral vectors for gene therapy Hartmann, Laura January 2007 (has links) Die vorliegende Arbeit beschäftigt sich mit der Synthese monodisperser, multifunktionaler Poly(amidoamine) (PAAs). Die Klasse der PAAs ist besonders interessant für eine Anwendung im Bereich der Biomedizin, da sie meist nicht toxisch ist, eine sehr geringe Immunogenizität zeigt und eine erhöhte Zellmembranpermeabilität besitzt. Allerdings ist der Einsatz linearer PAAs bisher limitiert, da ihre Synthese nur den Zugang von hoch-polydispersen Systemen mit einer streng alternierenden oder statistischen Verteilung von Funktionalitäten erlaubt. Es ist daher von großem Interesse diese Polymerklasse durch die Möglichkeit eines sequenzdefinierten Aufbaus und der Integration von neuen Funktionalitäten zu verbessern. Um dies zu ermöglichen, wurden, vergleichbar mit der etablierten Festphasensynthese von Peptiden, schrittweise funktionale Disäure- und Diamin-Bausteine an ein polymeres Träger-Harz addiert. Der sequenzielle Aufbau ermöglicht die Synthese monodisperser PAAs und die Kontrolle über die Monomersequenz. Die Wahl der Monomer-Bausteine und ihrer Funktionalitäten kann dabei für jede Addition neu getroffen werden und entscheidet so über die Sequenz der Funktionalitäten im Polymerrückgrat. Die verwendete Chemie entspricht dabei der Standardpeptidchemie, so dass mit Hilfe eines Peptidsynthese-Automaten die Synthese vollständig automatisiert werden konnte. Die Verwendung spezieller Trägerharze, die bereits mit einem synthetischen Polymerblock wie PEO oder auch mit einem Peptid vorbeladen waren, erlaubt die direkte Synthese von PEO- und Peptid-PAA Blockcopolymeren. Da die hier dargestellten PAAs später auf ihre Eignung als multivalente Polykationen in der Gentherapie getestet werden sollten, wurden zunächst Bausteine gewählt, die den Einbau verschiedener Aminfunktionalitäten ermöglichen. Die Bausteine müssen dabei so gewählt sein, dass sie kompatibel sind mit der Chemie des Peptidsynthesizers und eine quantitative Addition ohne Neben- oder Abbruchreaktionen garantieren. Darüber hinaus ist der Einbau von Peptidsequenzen und Disulfid-Einheiten in die PAA-Kette möglich, die z. B. für einen selektiven Abbau des Polymers im Organismus genutzt werden können. Zusammenfassend lässt sich feststellen, dass die in dieser Arbeit vorgestellten PAA-Systeme großes Potenzial als nicht-virale Vektoren für die Gentransfektion bieten. Sie sind nicht toxisch und zeigen Zellaufnahme-Effizienzen von bis zu 77%. Die Gentransfereffizienz ist im Vergleich zu etablierten Polymer-Vektoren zwar noch sehr gering, aber die bisherigen Versuche zeigen bereits eine mögliche Ursache, nämlich die schlechte Freisetzung des Genmaterials innerhalb der Zelle. Eine Lösung dieses Problems bietet jedoch die weitere Modifizierung der PAA-Systeme durch den Einbau von Sollbruchstellen. Diese Sollbruchstellen ermöglichen einen programmierten Abbau des Polymers innerhalb der Zelle und damit sollte die Freisetzung des Genmaterials vom Träger deutlich erleichtert werden. Mögliche Bruchstellen sind z. B. enzymatisch gezielt spaltbare Peptideinheiten oder Disulfid-Einheiten, wie sie bereits als Bausteine für die PAA-Synthese vorgestellt wurden (vergl. Kapitel 4.4). Da nur innerhalb der Zelle ein reduzierendes elektrochemisches Potential besteht, werden z. B. Disulfid-Einheiten auch nur dort gespalten und bieten außerhalb der Zelle ausreichende Stabilität zum Erhalt der Polyplexstruktur. Neben einer Anwendung in der Gentherapie bieten die hier vorgestellten PAA-Systeme den Vorteil einer systematischen Untersuchung von Struktur-Eigenschafts-Beziehungen der Polyplexe. Es wurden verschiedene Zusammenhänge zwischen der chemischen Struktur der PAA-Segmente und der Art und Stärke der DNS-Komprimierung aufgezeigt. Die Komprimierungsstärke wiederum zeigte deutlichen Einfluss auf die Internalisierungsrate und damit auch Transfektionseffizienz. Darüber hinaus zeigte sich ein drastischer Einfluss des PEO-Blocks auf die Stabilisierung der Polyplexe sowie deren intrazelluläre Freisetzung bei Zusatz von Chloroquin. Dennoch bleiben aufgrund der Komplexität der Zusammenhänge noch viele Mechanismen der Transfektion unverstanden, und es muss Aufgabe folgender Arbeiten sein, das Potential der hier eingeführten monodispersen PAA-Systeme weiter auszuloten. So wäre z. B. eine Korrelation der Kettenlänge mit den Parametern der Polyplexbildung, der Zellaufnahme und Transfektionseffizienz von großem Interesse. Darüber hinaus bietet der Einbau von Sollbruchstellen wie kurzen Peptidsequenzen oder den hier bereits eingeführten Disulfid-Einheiten neue Möglichkeiten der gezielten Freisetzung und des programmierten Abbaus, die näher untersucht werden müssen. Neben der Anwendung im Bereich der Gentransfektion sind außerdem andere Gebiete für den Einsatz von monodispersen multifunktionalen PAAs denkbar, da diese kontrollierbare und einstellbare Wechselwirkungen ermöglichen. / Recently, linear poly(amidoamine)s (PAAs) have received considerable attention due to their excellent biocompatibility and ease of synthesis.[1] PAAs are multifunctional polymers, which often exhibit low inherent immunogenicity and reduced cyto- as well as hemotoxicity in contrast to established, cationic polymers such as poly(ethylene imines) (PEI) or poly(L-lysines) (PLL).[2] This makes PAAs highly suitable for biomedical and pharmacological applications in the fields of drug and gene delivery.[1,2] However, the full potential of these polymers cannot be accessed since the synthesis proceeds via an uncontrolled polyaddition reaction leading to ill-defined products with Mw/Mn ≥ 2. This does not only make rational design of polymer properties and the precise positioning of functionalities along the polymer backbone difficult, furthermore product registration becomes complicated because legislation requires increasingly more defined products. Here we present a novel synthesis route towards multifunctional, sequence-defined polyamides.[3] A fully automated, solid-phase polymer synthesis was developed and utilized to obtain linear PAA segments. These exhibit no molecular weight or chemical distributions due to their monodispersity (Mw/Mn = 1) and their controlled monomer sequence. The compatibility of the PAA-synthesis with the standard Fmoc/tBu solid-phase supported peptide synthesis has been preserved, making this route a versatile approach to peptide-PAA (Pep-PAA) and poly(ethylene oxide)-PAA (PEO-PAA) conjugates. Several Pep-PAA and PEO-PAA conjugates were synthesized, exhibiting PAA segments with different cationic functionalities. These conjugates were analyzed concerning their cytotoxicity showing very promising results. Additionally their potential to complex plasmid-DNA and to form so-called polyplexes for non-viral gene delivery was tested. A strong relationship between the monomer sequence and the polyplex structure was observed, depending on the balance and total amount of tertiary, secondary and primary amine functionalities within the PAA-segment. Moreover the monomer sequence has a strong influence on the biological properties such as the cell-internalization of polyplexes as well as the transfection activity. This clear correlation between the chemical assembly and the resulting biological properties may help to further the understanding of the mechanisms of gene delivery by polymeric carriers and hence to promote the rational design of better suited systems. Even if the transfection activity for the PAA-polpylexes might still be not comparable to the established “gold standard” PEI, their low level of toxicity and the possibility to improve the system by adjusting the monomer sequence shows great potential as carrier systems in drug or gene delivery. Poly(amidoamine) Gentherapie nicht-viral monodispers Monomersequenz poly(amidoamine) gene therapy non-viral monodisperse monomer-sequence Chemistry and allied sciences
415	Entwicklung biohybrider Redoxsysteme auf der Grundlage "smarter" Redoxpolymere / Development of biohybrid redox systems on the basis of "smart" redox polymers Nagel, Birgit January 2009 (has links) In dieser Arbeit wird die Entwicklung und Charakterisierung neuer „smarter“ Redoxhydrogele mit drei verschiedenen funktionellen Eigenschaften und deren erfolgreicher Einsatz zur elektrochemischen Kontaktierung von Oxidoreduktasen beschrieben. Diese neuen Redoxpolymere 1. tragen kovalent integrierte Redoxzentren umgeben von einer hydrophilen Polymermatrix, 2. reaktive Kopplungsgruppen für den Aufbau selbstassemblierter Polymerschichten auf Elektrodenoberflächen und 3. lassen sich in ihrer Redoxaktivität durch Verwendung „intelligenter“ Polymere über externe Stimuli kontrollieren. Die Redoxhydrogele wurden nach dem Vorbild eines Baukastensystems in einfachen Ein-Stufen-Synthesen synthetisiert. Dazu wurden verschiedene Redoxzentren (Ferrocen, 1,10-Phenanthrolin-5,6-dion und 4-Carboxy-2,5,7-Trinitro-9-fluorenon), reaktive Kopplungsgruppen (Epoxy-, Amino-, Thiol- oder Disulfidfunktionen) und Polymermatrices (Poly-(N-Isopropylacrylamid) (PNIPAM) und Poly(ethylenglykolmethacrylat) (PEGMA)) in unterschiedlichen Zusammensetzungen miteinander copolymerisiert. Die Polymere wurden in Form von dünnen Polymerfilmen über die wiederholenden Funktionalitäten auf Elektrodenoberflächen aufgebracht und physiko- und elektrochemisch charakterisiert. Durch die erstmals gezeigte, derartige Ankopplung der Polymere, entstehen dreidimensionale, hydrophile selbstassemblierte Polymerschichten. Die Elektronentransferwege sind kurz und der Elektronentransfer effizient. Diese Polymer-modifizierten Elektroden wurden für die Kontaktierung von zwei exemplarisch ausgewählten Oxidoreduktasen eingesetzt, die Nicotinsäureamid-adenin-dinucleotid-abhängige Glucosedehydrogenase (NAD-GDH), welche ein freibewegliches Coenzym und die Pyrrolochinolinchinon-abhängige Glucosedehydrogenase (PQQ-GDH), welche ein prosthetisches Coenzym verwenden. Die Redoxaktivitäten des PNIPAMFoxy- und PEGMA-Fc-Polymers ließen sich durch externe Stimuli in Form von Temperatur und Calciumkonzentrationen kontrollieren. Ein Modell für die Komplexierung der Calciumionen durch die PEG-Seitenketten unter Ausbildung Kronenether-ähnlicher Strukturen und der daraus resultierenden Steigerung des Elektronentransfers wurde gezeigt. / This work describes the development and characterization of new, smart redox polymeres with three functionalities and their use in electrochemical wiring of oxidoreductases. These polymers 1. bear redox-active sites surrounded by hydrophilic polymeric matrix 2. surface-reactive groups to create self-assembled monolayers on electrodes 3. ionic-tunable redox activities by using stimuli-responsive polymers The syntheses of the redoxpolymers were resolved in simple one-step approaches using a building block system. Different mediators (ferrocene, 1,10-phenanthroline-5,6-dione and 4-carboxy-2,5,7-trinitro-9-fluorenone), reactive anchoring groups (groups epoxide, amine, thiol and disulfide) and polymer matrices (poly-(N-isopropylacrylamide) (PNIPAM), poly(ethylene glycol methacrylate) (PEGMA)) were copolymerized in different compositions. The polymers were anchored to electrode surfaces via the repetitive functionalities and physico- and electrochemical characterized. This kind of anchoring of the redoxpolymers was shown for the first time and three-dimensional hydropilic self-assembled polymer monolayers are created. The electron transfer pathways are short and the electron tranfer efficient. The polymer-modified electrodes were applied for wiring two oxidoreductases, nicotinamide-adenine-dinucleotide-dependent glucose dehydrogenase (NAD-GDH) with a diffusing coenzyme and the pyrroloquinoline quinone-dependent glucose dehydrogenase (PQQ-GDH) with a prosthetic coenzyme. The redox activities of PNIPAMFoxy and PEGMA-Fc-SS are tuneable with external stimuli like temperature and calcium concentrations. A model for the complexation of calcium by PEG side chains and the explanation of the resulting effects was shown. Poly-N-Isopropylacrylamid Polyethylenglykol Ferrocen Phenanthrolindion Carboxynitrofluorenon poly-N-isopropylacrylamide polyethylene glycol ferrocene phenanthrolindione carboxynitrofluorenone Life sciences
416	Composite Poly(dimethoxyaniline) Electrochemical Nanobiosensor For Glufosinate And Glyphosate Herbicides. Songa, Everlyne Apiyo. January 2008 (has links) <p>In this thesis, I present a simple, sensitive and low cost electrochemical nanobiosensor for quantitative determination of the herbicides glufosinate, glyphosate and its metabolite aminomethylphosphonic acid (AMPA). Firstly, the nanostructured poly(2,5-dimethoxyaniline) (PDMA) materials were synthesized on gold electrode by the electrochemical &ldquo / soft template&rdquo / method using poly(4-styrenesulfonic acid) (PSS) as the dopant and structure-directing molecule. Fourier transform infrared (FTIR) spectroscopy, UV-Vis Spectroscopy, Transmission electron microscopy (TEM) and Scanning electron microscopy (SEM) studies inferred successful doping of the nanostructured PDMA film by PSS and that the template PSS directed the synthesis of both nanotubes and nanoparticles of PDMA with diameters less than 100 nm.</p> Poly(2,5-dimethoxyaniline) Poly(4-styrenesulfonic acid) Nanostructured Polymers Horseradish Peroxidase Electrochemical Nanobiosensor Glufosinate Glyphosate Herbicides Aminomethylphosphonic acid Inhibition.
417	Environmentally Friendly Plasticizers for PVC : Improved Material Properties and Long-term Performance Through Plasticizer Design Lindström, Annika January 2007 (has links) Linear and branched poly(butylene adipate) polyesters with number-average molecular weights ranging from 700 to 10 000 g/mol, and degrees of branching ranging from very low to hyperbranched were solution cast with PVC to study the effects of chemical structure, molecular weight, end-group functionality, and chain architecture on plasticizing efficiency and durability. Miscibility was evaluated by the existence of a single glass transition temperature and a shift of the carbonyl group absorption band. Desirable mechanical properties were achieved in flexible PVC films containing 40 weight-% of polyester plasticizer. Methyl-ester-terminated polyesters with a low degree of branching and an intermediate molecular weight enhanced the plasticizing efficiency, as shown by greater elongation, good miscibility, and reduced surface segregation. A solid-phase extraction method was developed to extract the low molecular weight products that migrated from pure poly(butylene adipate) and PVC/ poly(butylene adipate) films during aging in water. The effects of branching, molecular weight, end-group functionality, and polydispersity on plasticizer permanence were evaluated by quantification of low molecular weight hydrolysis products, weight loss, surface segregation, and the preservation of material properties during aging. A more migration-resistant polymeric plasticizer was obtained by combining a low degree of branching, hydrolysis-protecting end-groups, and higher molecular weight of the polyester. Films plasticized with a slightly branched polyester showed the best durability and preservation of material and mechanical properties during aging. A high degree of branching resulted in partial miscibility with PVC, poor mechanical properties, and low migration resistance. The thermal stability of polyester-plasticized films was higher than that of films containing a low molecular weight plasticizer, and the stabilizing effect increased with increasing plasticizer concentration. / QC 20100805 poly(butylene adipate) poly(vinyl chloride) plasticizers miscibility mechanical properties surface segregation migration degradation products Polymer chemistry Polymerkemi
418	Intrinsic Properties of Poly(Ether-B-Amide) (PEBAX®1074) for Gas Permeation and Pervaporation Shangguan, Yiyi January 2011 (has links) Poly(ether-b-amide) (Pebax® grade 1074) is a waterproof breathable block copolymer containing soft poly(ethylene oxide) and rigid polyamide 12 segments. Its intrinsic gas permeabilities to nitrogen, oxygen, methane, helium, hydrogen, and carbon dioxide were tested under different feed pressures (0.3 – 2.5 MPa) and temperatures (20 – 80 °C). This helps to obtain a comprehensive understanding of the polymer, because prior work reported in the literature addressed only a few gases and used inconsistent membrane preparation and test methods. Relatively high polar (or quadrupolar)/nonpolar gas selectivity were observed. CO2/N2 selectivity was demonstrated to be as high as 105±0.4 in Pebax®1074, with CO2 permeability coefficient of approximately 180±1 Barrer at room temperature. Additionally, the effects of solvent used in membrane preparation, heat treatment, membrane thickness, and polymer solution concentration on the membrane permeability were evaluated. Pebax® is a highly breathable material, thus its application as breathable chemically-resistant protective clothing was studied. Dimethyl methylphosphonate (DMMP) – a sarin simulant – was selected as the challenge agent. The liquid pervaporation of pure water (simulating perspiration) and pure DMMP were measured for Pebax®1074, Pebax®2533, nitrile, latex, poly(vinyl chloride), low density polyethylene, silicone, and silicone-polycarbonate copolymer under pervaporation mode. Pebax®1074 was not only the most water permeable material but also the most selective of all the tested materials for water/DMMP – making it a very promising material for this application. Chemical Engineering
419	Mechanistic studies of the metal catalyzed formation of polycarbonates and their thermoplastic elastomers Choi, Wonsook 15 May 2009 (has links) Studies concerning the formation of industrially useful polycarbonates are the focus of this dissertation. Of particular importance is the biodegradable polymer, poly(trimethylene carbonate) which has a wide range of medical applications. The production of polycarbonates can be achieved by the ring-opening polymerization of cyclic carbonate, or the copolymerization of carbon dioxide and oxiranes or oxetanes. For the production of polycarbonates from these monomers, Schiff base metal complexes have been designed, synthesized, and optimized as catalysts. Detailed kinetic and mechanistic studies have been performed for the ring-opening polymerization of cyclic carbonates, as well as the copolymerization of carbon dioxide and oxiranes or oxetane. In addition, the copolymerization of cyclic carbonates and cyclic esters to modify the mechanical and biodegradable properties of materials used for medical devices has been studied using biocompatible metal complexes. In the process for ring-opening polymerizations of trimethylene carbonate or lactides, Schiff base metal complexes (metal = Ca(II), Mg(II) and Zn(II)) have been shown to be very effective catalysts to produce high molecular weight polymers with narrow polydispersities. Kinetic studies demonstrated the polymerization reactions to proceed via a mechanism first order in [monomer], [catalyst], and [cocatalyst] if an external cocatalyst is applied, and to involve ring-opening by way of acyl-oxygen bond cleavage. The activation parameters (ΔH≠, ΔS≠ and ΔG≠) were determined for ringopening polymerization of trimethylene carbonate, ring-opening polymerization of lactides, and copolymerization of trimethylene carbonate and lactide. In the process for copolymerization of carbon dioxide and oxetane, metal salen derivatives of Cr(III) and Al(III) along with cocatalyst such as n-Bu4NX or PPNX (PPN = bis(triphenylphosphine)iminium, and X = Br, Cl and N3) have been shown to be effective catalysts to provide poly(trimethylene carbonate) with only trace amount of ether linkages. The formation of copolymer is proposed not to proceed via the intermediacy of trimethylene carbonate, which was observed as a minor product of the coupling reaction. To support this conclusion, ring-opening polymerization of trimethylene carbonate has been performed and kinetic parameters have been compared with those from the copolymerization of carbon dioxide and oxetane. Polycarbonates Poly(trimethylene Carbonate) Poly(lactide) Copolymers Thermoplastic Elastomers Biometal catalysts Ring-opening Polymerization Biodegradation Medical Materials
420	Silicon-based Preceramic Polymers And Their Uses In Polymer Composites: Synthesis, Characterization And Processing Donmez Karadal, Sibel 01 December 2011 (has links) (PDF) The objectives of this study are to synthesize poly(dimethylsilane) (PDMS) preceramic polymer and to investigate its effect on morphology, flame retardant and mechanical properties of polypropylene (PP) based composites. There are mainly two parts in this thesis. In the first part, PDMS was synthesized by electrochemical polymerization of dichlorodimethylsilane, which was dissolved in 1,2 dimethoxyethane (DME) solvent consisting of tetrabutyl ammonium perchlorate (TBAP), as supporting electrolyte. PDMS was obtained in powder form and characterized with Fourier transform infrared, ultraviolet-visible and proton nuclear magnetic resonance spectroscopic analyses, thermogravimetric analysis (TGA) and scanning electron microscopy (SEM). Since PDMS has some impurities coming from TBAP and DME, alternatively, the PDMS synthesis was done by electrochemical reduction of dichlorodimethylsilane without using solvent and/or supporting electrolyte for seven days. PDMS was produced as pure and characterized with the same methods used for previous synthesis. In the second part of this thesis, PP based composites with additives were prepared by using a twin-screw extruder and injection molding machine and were characterized with limiting oxygen index (LOI), horizontal burning, TGA, differential scanning calorimetry (DSC), tensile and impact tests and SEM analysis. Triphenyl phosphate, boron phosphate, magnesium hydroxide, intumescent flame retardants (IFR) (melamine phosphate (MP) and pentaerythritol (PER)), antimony trioxide and poly(methylsilsesquioxane) were additives used in this study other than PDMS. According to LOI test results, the highest LOI value among the PDMS composites was obtained in 1% PDMS, 14.25% MP and 4.75% PER (w/w) containing composite as 24%, whereas the LOI value of neat PP was measured as 17.5%. It was determined that elastic moduli of all the composites studied were higher than neat PP. TP Polymers, Plastics 1080-1185

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