Polymer films and brushes self-construction by electrochemically triggered morphogens / Auto-construction de films et de brosses de polymères par morphogène généré électrochimiquement

Dochter, Alexandre

23 September 2014

Les multicouches de polyelectrolytes, systèmes auto-assemblés par adsorption successive de polycations et de polyanions, constituent un matériau d’intérêt pour la fonctionnalisation de surface. Ce type de revêtement possède toutefois quelques limitations majeures : leur construction est lente et fastidieuse ; leur tenue mécanique et chimique est faible. Récemment, une méthode basée sur l’auto-construction de films par l’utilisation d’un morphogène, i.e. un gradient de catalyseur généré depuis une surface, a été développé permettant ainsi une rapide construction de revêtements robustes. Cette technique reste toutefois limitée à des systèmes particuliers basés sur la chimie click ou sur des interactions hôtes-invités. Nos travaux ont permis de diversifier cette approche de construction tout-en-un par l’utilisation de morphogènes. Dans un premier temps, des brosses de polymères ont été construites en une étape depuis une surface par la réaction de polymérisation ATRP. Cette réaction a été catalysée par la formation d’ions Cu(I) (le morphogène) par électrochimie depuis la surface de travail. L’approche morphogénique a également été utilisée afin de construire des films de polyélectrolytes et de polyampholytes en une étape par la génération électrochimique d’un gradient de protons (le morphogène) depuis la surface de travail. Ces films ont été fonctionnalisés pour présenter une activité enzymatique. / Polyelectrolyte multilayers, i.e. self-assembled systems based on successive polycation and polyanion adsorptions, constitute interesting materials for surface functionalization. These coatings possess several limitations: they are weak towards chemical and mechanical constraint and their buildup is long and tedious. Recently, a new method based on the self-construction of films by the means of a morphogen (a catalyst gradient generated from a surface) has attracted attention since it allows the quick self-assembly of robust films. Nevertheless, this technique was quite limited to peculiar systems based on click chemistry or on host-guest interactions.This present work generalize the one-pot morphogenic approach to other systems. In the first place, polymer brushes were built up from a surface by ATRP polymerization. The Cu(I) catalyst (the morphogen) was electrochemically generated at the interface.The morphogenic approach was later used to buildup polyelectrolytes and polyampholyte films in a one-pot manner by electrochemically generating protons (the morphogens) at the interface. These films exhibited an enzymatic activity.

Auto-assemblage

Interface

Polyéléctrolytes

Enzymes

Biomatériaux

Électrochimie

Morphogène

ATRP

Microbalance à cristal de quartz

Self-assembly

Interface

Polyelectrolytes

Enzymes

Biomaterials

Electrochemistry

Morphogen

ATRP

Quartz crystal microbalance

541.3

Fotossensibilizadores nanoestruturados por sistema camada por camada

Faria, Ana Claudia Rangel

28 July 2011

A busca por materiais que possam ser modificados em nível molecular tem sido o alvo de numerosas pesquisas no mundo. Desta maneira, as técnicas de fabricação de filmes finos se destacam devido à possibilidade de se reduzir custos e melhorar a eficiência de sistemas como, por exemplo, os fotossensíveis. Neste contexto, o objetivo deste trabalho foi a obtenção e caracterização de filmes finos através da técnica de automontagem (técnica "camada por camada" ou Layer-by-Layer). Os filmes foram depositados sobre diversos substratos (lamínula de vidro, silício e poliestireno). Nesse trabalho foram depositados dois conjuntos diferentes de multicamadas combinados com duas proporções diferentes de cada sistemas de soluções. O sistema catiônico foi composto pela solução do polieletrólito orgânico PDDA e a solução coloidal do semicondutor inorgânico seleneto de cádmio (CdSe). O sistema aniônico foi composto por solução do poli(ácido acrílico) (PAA) e solução de óxido de titânio (TiO2), respectivamente. Os materiais utilizados para a obtenção dos filmes e os filmes finos nanoestruturados produzidos foram caracterizados por meio de diversas técnicas. As regiões de absorção das soluções coloidais inorgânicas foram determinadas por espectroscopia de absorção molecular no ultravioleta-visível (UV-Vis) e apresentaram absorção em 320 nm (TiO2) e 440 nm (CdSe). O diâmetro das nanopartículas inorgânicas de TiO2 e de CdSe foram mensurados por difração de raios X (DRX) e microscopia eletrônica de transmissão (MET), revelando valores em escala nanométrica. Observou-se no difratograma do pó nanoparticulado de TiO2 que a fase predominante no mesmo é a anatase, e que houve uma sobreposição dos picos de maior intensidade do TiO2 e do CdSe, ambos em 2q = 25,3°. O espectro de refletância difusa (RDUV-Visível) dos filmes automontados apresentou valores compatíveis com as das soluções formadoras dos filmes, indicando que os mesmos apresentam aplicação em dispositivos fotossensíveis. Através dos comprimentos de onda obtidos a partir das técnicas de UV-Vis e RDUV-Vis foi possível estimar os valores de energia de bandas proibidas (Ebg) para os semincondutores TiO2 e CdSe. As espessuras dos filmes foram determinadas pelas técnicas de perfilometria e por microscopia eletrônica de varredura (MEV), e encontram-se na ordem de grandeza micrométrica. Pelas micrografias de MEV foi possível avaliar a superfície dos filmes que revelaram alta rugosidade, formação de ilhas de TiO2 e aglomeração de grãos esféricos (Se). Nas imagens de MET, observou-se a distribuição das nanopartículas dos semicondutores na seção transversal dos filmes, corroborando as aglomerações observadas por MEV. / The search for materials that can be modified at molecular level has been the subject of several studies worldwide. Thus, the production techniques of thin films stand out due to the possibility of reducing costs and improving the efficiency of systems, such as photosensitive systems. In this context, the aim of this study was to obtain and characterize thin films using the self-assembly technique (layer by layer technique or LbL). The thin films were deposited on different substrates (glass coverslips, silicon and polystyrene). In this work two different multilayer sets combined with two different proportions of each solution system were deposited. The cationic system was composed by the poly(diallyldimethilammonium) (PDDA) organic polyelectrolyte solution and the cadmium selenide (CdSe) inorganic semiconductor colloidal solution. The anionic system was composed by the poly(acid acrylic) (PAA) solution and the titanium dioxide (TiO2) solution, respectively. The materials used for the achievement of films and nanostructured thin films produced were characterized through various techniques. The absorption regions of inorganic colloidal solutions were determined by UV-Vis spectroscopy and presented absorption at 320 nm (TiO2) and 440 nm (CdSe). The resulting inorganic nanoparticles diameter of TiO2 and CdSe were measured by X ray diffraction (XRD) and transmission electron microscopy (TEM), resulting in values at nanometric scale. It was observed in the nanoparticle TiO2 powder diffractogram that anatase is the most abundant phase, and that there was an overlap of the highest intensity diffraction peaks of TiO2 and CdSe, both at 2q = 25.3 °. The diffuse reflectance spectrum (RDUV-Vis) of self-assembled films presented values compatible with those of the film forming solutions. Using the wavelengths obtained from the UVVis and Vis-RDUV techniques it were possible to evaluate values for the energy band gap (Ebg) seminconductors TiO2 and CdSe. The thicknesses of the films were determined by profilometry and scanning electron microscopy (SEM) techniques, and they are in the micrometric order of magnitude. Using the SEM micrographs, it was possible to evaluate the surface of the films that show a high roughness, the formation of TiO2 clumps and the agglomeration spherical selenium clusters. In TEM images, the distribution of the semiconductor nanoparticles in cross-section of films can be observed, confirming agglomerations observed by SEM.

Engenharia de materiais e metalúrgica

Filmes finos

LbL

Nanopartículas

Polieletrólitos

Semicondutores

Materiais - Propriedades mecânicas

Materiais - Testes

Nanotecnologia

LbL

Nanoparticles

Polyelectrolytes

Semiconductors

Thin films

Materials - Mechanical properties

Materials - Testing

Nanotechnology

Arranjos supramoleculares de drogas em lípides sintéticos e/ ou polieletrólitos: estabidade coloidal e atividade in vitro / Supramolecular assemblies of drugs in synthetic lipid and/ or polyelectrolytes: colloid stability and in vitro activity

Débora Braga Vieira

15 April 2008

Formação, estabilidade coloidal e atividade in vitro contra Candida albicans dos arranjos supramoleculares compostos por drogas, lípides catiônicos e/ ou polieletrólitos foram sistematicamente avaliados através de espalhamento de luz dinâmico para tamanho de partículas, análise de potencial-zeta, espectrofotometria UV-visível, efeitos de droga sobre a transição de fase gel para líquido-cristalina da bicamada catiônica e quantificação de incorporação de droga nos diferentes sistemas. Arranjos supramoleculares de drogas antifúngicas como miconazol ou anfotericina B foram obtidos por solubilização das drogas em fragmentos de bicamada catiônica de brometo de dioctadecildimetilamônio ou como partículas de droga recobertas com uma camada do mesmo lípide catiônico. Como modelo de droga anticancerígena, a cisplatina foi incorporada com sucesso em polieletrólitos de carga oposta: quitosana e carboximetilcelulose. Cisplatina induziu substancial estabilização coloidal e redução de tamanho de partículas de carboximetilcelulose-quitosana, possivelmente atuando como agente de ligação cruzada entre os dois polieletrólitos. Assim também, arranjos supramoleculares de anfotericina B em baixa e em alta proporção molar droga: lípide catiônico foram revestidos com polieletrólitos como carboximetilcelulose, cloreto de poli(dimetildialilamônio) e polilisina formando nanopartículas catiônicas. Nanopartículas catiônicas de anfotericina B apresentaram estabilidade coloidal e atividade fungicida ótima. Quanto aos arranjos do miconazol com os fragmentos de bicamada catiônica, observou-se o mesmo com a vantagem de se obter ação sinérgica entre o lípide catiônico e a droga. Dois sítios de interação com fragmentos de bicamada catiônica foram identificados para o miconazol: (1) as bordas hidrofóbicas disponíveis à temperatura ambiente; (2) os sítios no seio da bicamada ocupados com o aumento de temperatura. A potente ação antimicrobiana do lípide catiônico brometo de dioctadecildimetilamônio (DODAB) per se, motivou um estudo sistemático da ação antimicrobiana comparada de DODAB e brometo de cetiltrimetilamônio (CTAB) contra Candida albicans. A adsorção destes compostos e seus agregados sobre a célula diminuiu seguindo a ordem: CTAB > fragmentos de bicamada de DODAB > vesículas grandes de DODAB. A ausência de vazamento de compostos fosforilados intracelulares de baixo peso molecular, DNA ou proteína em presença dos catiônicos evidenciou mecanismo de ação antimicrobiana independente de lise celular. A adsorção dos compostos catiônicos sobre células de Candida albicans mudou o sinal de potencial da superfície celular de negativo para positivo, exibindo uma relação clara entre a carga positiva sobre a célula e morte celular. / The formation, colloid stability and activity in vitro against Candida albicans of several supramolecular assemblies composed of drug, cationic lipid and/or polyelectrolytes were systematically evaluated by means of dynamic light scattering for particle sizing, zeta- potential analysis, UV-visible spectroscopy, effect of drug on gel-to-liquid-crystalline phase transition of the cationic bilayer and determination of drug loading. Supramolecular assemblies of antifungal drugs such as miconazole and amphotericin B were obtained by solubilization of the drugs in cationic bilayer fragments composed of dioctadecyldimethylammonium bromide or coverage of drug particles with a layer of the quoted cationic lipid. As a model of anticancer drug, cisplatin was sandwiched between two oppositely charged polyelectrolytes: chitosan and carboxymethylcellulose. Cisplatin induced reduction in particle size acting as a cross-linker between polyelectrolytes. For amphotericin B, at low and high molar proportion drug to cationic lipid, similar supramolecular assemblies were coated by polyelectrolytes such as carboxymethylcellulose, poly(diallyldimethylammonium) and polylysine yielding cationic nanoparticles that presented optimal colloid stability and fungicidal activity. Miconazole became attached at the hydrophobic edges of bilayer fragments at room temperature and/or, upon an increase in temperature, inserted in the bilayer core. Curiously, this last formulation in the cationic lipid yielded a synergistic action against Candida albicans. Dioctadecyldimethylammonium bromide (DODAB) is an excellent antimicrobial agents per se. Its mechanism of antimicrobial action was compared to the one for hexadecyltrimethylammonium bromide (CTAB). Adsorption of these compounds on the cells decreased going from CTAB to DODAB bilayer fragments and to large vesicles. Absence of leakage of small phosphorylated compounds, proteins or DNA from fungus indicated a mechanism of action different from cell lysis. Adsorption of the cationic compounds changed the sign of the cell zeta-potential from negative to positive. There was a clear relationship between positive charge on fungus and death.

Anfotericina B

Antifúngicos

Brometo de dioctadecildimetilamônio

Candida albicans

Cisplatina

Miconazol

Polieletrólitos

Polímeros

Quimioterápicos

Amphotericin B

Candida albicans

Cisplatin

Dioctadecyldimethylammonium bromide

Miconazole

Polimers

Polyelectrolytes

Development of new types of mechanocatalytic systems / Développement de nouveaux systèmes enzymatiques mécano-transductifs

Zahouani, Sarah

25 September 2017

Le fascinant processus par lequel les signaux mécaniques sont transformés en réactions biochimiques dans la nature est appelé mécano-transduction. Le but de ma thèse a été de mimer la Nature en élaborant de nouveaux systèmes enzymatiques mécano-transductifs, i.e des matériaux capables de moduler une catalyse enzymatique lorsqu’ils sont sollicités mécaniquement. Nous avons d’abord étudié l’effet de l’étirement sur les chaînes constitutives de films multicouches de polyélectrolytes, matrices souvent utilisées pour le développement de biomatériaux intelligents. Dans le cadre d’une nouvelle stratégie axée sur la modulation mécanique de la conformation, nous avons ensuite élaboré des matrices étirables à base de poly(éthylène glycol)s. Nous avons en particulier développé de tout nouveaux revêtements covalents appelés nanogels qui se sont avérés être déposables sur le silicone étirable et fonctionnalisables avec différentes biomacromolécules, ouvrant ainsi de nouvelles routes biomimétiques. / The fascinating process by which mechanical signals are transformed into biochemical reactions in Nature is called mechanotransduction. The goal of my PhD was to mimic Nature by elaborating new types of mechanocatalytic materials, i.e materials able to modulate a catalytic activity when mechanically stimulated. We first aimed at understanding the impact of stretching on the structural properties of polyelectrolyte multilayers films, polymeric matrices often used for the design of smart biomaterials. Within the framework of a new strategy essentially relying on mechanically induced conformational changes, we then developed stretchable polymeric matrices based on poly(ethylene glycol)s. We more particularly designed new types of covalent coatings, called nanogels. We showed that these architectures were buildable on stretchable silicone and that they could be functionalized with different types of biomacromolecules; thus opening new biomimetic routes.

Mécano-transduction

Conformation

Étirement

Catalytique

Polyélectrolytes

Poly(etylene glycol)

Hydrogels

Nanogels,

Couche par couche

Mechanotransduction

Conformation

Stretching

Catalytic

Polyelectrolytes

Poly(ethylene glycol)

Hydrogels

Nanogels

Step-by-step

541.3

Development of a conducting multiphase polymer composite for fuel cell bipolar plate

Alo, Oluwaseun Ayotunde

06 1900

D. Tech. (Department of Mechanical Engineering, Faculty of Engineering and Technology), Vaal University of Technology. / On account of their lightweight, low-cost, corrosion resistance, and good formability, conductive polymer composites (CPCs) are promising for the production bipolar plate (BP) for polymer electrolyte membrane fuel cell (PEMFC). However, a high conductive filler loading is needed to impart the required level of electrical conductivity to the insulating polymer matrix and as a consequence, the toughness of the plate deteriorates considerably. By using immiscible blend of polymers that have complementary hardness and ductility as matrix, with conducting multi-fillers of different morphologies, it is possible to optimize the matrix strength characteristics and favour the formation of conducting network to produce CPC meeting BP performance standards. Of course, a lot will depend on the formulation of the most favourable composition and production variables. In this regard, polypropylene-epoxy and polyethylene-epoxy blends, filled with zero- and two-dimensional carbon forms – graphite, carbon black (CB), and graphene (Gr) – were investigated over an extensive range of compositions and compression moulding pressures, in this study. Several compounding runs (using melt mixing), at different stages, followed by compression molding, were done. The goal is to obtain combination of composite formulation and processing conditions that will produce the most promising combination of properties for BP application. In the first stage of the investigations, by using thermogravimetric analysis, two-stage decomposition behavior of PP-epoxy and PE-epoxy blends was revealed, which confirms the immiscibility of PP and PE with epoxy resin. Scanning electron microscope (SEM) micrographs of the PP-epoxy and PE-epoxy blends revealed a co-continuous structure, which can be attributed to the close-to-symmetric composition of the blend and compatibilizers added. Preferential localization of synthetic graphite (SG), CB, and Gr in the polymer blends was also revealed by the SEM micrographs. This confirms the fact that CPCs based on PP-epoxy and PE-epoxy blends can be explored further. PP-epoxy and PE-epoxy blends filled with only SG, 30 – 80 wt %, were produced and characterized for their electrical conductivity and flexural properties. In-plane electrical conductivity ranged from 12.09 to 68.03 Scm-1 for PP-epoxy/SG and 11.68 to 72.96 Scm-1 for PE-epoxy/SG composites produced. These are higher than values reported for several single matrix polymer composites at similar filler loadings. With reference to the United States Department of Energy performance targets for BPs, PE-epoxy/SG composites performed better in terms of electrical conductivity, while PP-epoxy/SG composites exhibited better flexural properties. Thereafter, using SG and CB double filler, PE-epoxy/SG/CB composites performed better than PP-epoxy/SG/CB composites in terms of electrical conductivity, while PP-epoxy/SG/CB composites exhibited superior flexural properties than the PE-epoxy/SG/CB composites at similar filler loadings. However, with respect to the DOE targets, composites based on PP-epoxy blend exhibited a more promising combination of electrical conductivity and flexural properties than PE-epoxy blend matrix. PP-epoxy filled with SG/CB was studied further, by using graphene (Gr) as second minor filler. In-plane and through plane electrical conductivities as well as thermal conductivity and thermal diffusivity of the PP-epoxy/SG/CB/Gr composites increased as total filler content was increased from 65 to 85 wt%. It implies that more conductive networks between filler particles were formed. Also, flexural strength, flexural modulus, and impact strength decreased as the total filler content increased from 65 to 85 wt%. The reduced flexural properties could be due to increased agglomeration of CB and Gr, and poor filler wetting at higher filler loadings and low matrix material, which leads to the formation of microvoids and a reduction of the load bearing capacity of composites. With respect to the DOE targets, PP-EP/SG/CB/Gr composite with 80 wt% (i.e., PP/EP/73G/6.2CB/0.8Gr) filler has the best combination of properties. Further improvement in properties of the PP-EP/SG/CB/Gr composite with 80 wt% filler was achieved by molding at higher pressures. As molding pressure was increased from 4.35 to 13.05 MPa, in-plane electrical conductivity increased from 116.31 to 144.99 Scm-1, while flexural strength increased from 29.62 to 42.57 MPa, satisfying the performance requirement targets for bipolar plates.

Conducive polymer composites

Polymer electrolyte membrane fuel cells

Bipolar plates

Multi filler

Dissertations, Academic -- South Africa.

Polymers.

Fuel cells.

Carbon fibers.

Polyelectrolytes.

Термодинамика взаимодействия полидиаллилдиметиламмоний хлорида с полиакриламидом : магистерская диссертация / Thermodynamics of the interaction of polydiallyldimethylammonium chloride with polyacrylamide

Кузнецова, Е. Д., Kuznetsova, E. D.

January 2021

Изучена равновесная сорбция паров воды образцами линейных ПДАДМАХ, ПАА и их смесей разного состава, а также сетчатых сополимеров ДАДМАХ/АА. Измерены теплоты растворения образцов в воде. Рассчитаны величины разностей химических потенциалов воды 1, полимерного компонента 2, средние удельные энергии Гиббса набухания сополимеров и растворения смесей в воде gm. С помощью термодинамического цикла рассчитаны средняя удельная энергия Гиббса смешения gx, средняя удельная энтальпия смешения hx и энтропийный вклад в смешение ПДАДМАХ с ПАА Tsx. Показано, что как для смесей ПДАДМАХ и ПАА, так и для сополимеров ДАДМАХ/АА с увеличением содержания акриламидного компонента существенно уменьшается водопоглощение. При этом меняется вид изотерм с S–образной на вогнутую, что свидетельствует об увеличении плотности упаковки полимеров. Установлено, что энергии Гиббса набухания сополимеров ДАДМАХ/АА, и растворения ПДАДМАХ и ПАА в воде отрицательны во всей исследованной области составов. С увеличением содержания АА термодинамическое сродство к воде закономерно понижается. Установлено, что смешение с водой ПДАДМАХ, ПАА и их смесей происходит с экзотермическим тепловым эффектом. При этом наблюдаются положительные отклонения от аддитивности во всей области составов, что свидетельствует о лучшем взаимодействии полимеров друг с другом, чем с водой. Обнаружено, что энергии Гиббса взаимодействия ПДАДМАХ с ПАА отрицательны во всей области составов смесей, но кривизна зависимости разная. Когда в составе один из компонентов преобладает, вторая производная энергии Гиббса положительна (∂2g/∂ω22> 0), т.е. полимеры термодинамически совместимы. В случае, если содержание компонентов близко друг к другу, (∂2g/∂ω22 <0). Это означает, что компоненты термодинамически не совместимы и образуют двухфазную коллоидную систему. При этом ПДАДМАХ с ПАА смешивается экзотермически во всей области составов, а энтропия меняет свой знак. / The equilibrium sorption of water vapor by samples of linear PDADMAC, PAA and their mixtures of different compositions, as well as cross-linked copolymers DADMAC/AA, has been studied. The heats of dissolution of samples in water were measured. The values of the differences in the chemical potentials of water 1, polymer component 2, and the average specific Gibbs energies of swelling of copolymers and dissolution of mixtures in water gm are calculated. Using the thermodynamic cycle, the average specific Gibbs energy of mixing gx, the average specific enthalpy of mixing hx, and the entropy contribution to mixing of PDADMAC with PAA Tsx were calculated. It was shown that both for mixtures of PDADMAC and PAA and for copolymers DADMAC/AA with an increase in the content of the acrylamide component, water absorption significantly decreases. In this case, the form of isotherms changes from S-shaped to concave, which indicates an increase in the packing density. It was found that the Gibbs energies of swelling of the DADMAC / AA copolymers and the dissolution of PDADMAC and PAA in water are negative in the entire studied range of compositions. With an increase in AA content, the thermodynamic affinity for water naturally decreases. It has been established that the mixing of PDADMAC, PAA and their mixtures with water occurs with an exothermic thermal effect. In this case, positive deviations from additivity are observed in the entire range of compositions, which indicates a better interaction of polymers with each other than with water. It was found that the Gibbs energies of the interaction of PDADMAC with PAA are negative in the entire range of mixture compositions, but the curvature of the dependence is different. When one of the components prevails in the composition, the second derivative of the Gibbs energy is positive (∂2g/ ∂ω22> 0), i.e. polymers are thermodynamically compatible. If the content of the components is close to each other, (∂2g/∂ω22 <0). This means that the components are thermodynamically incompatible and form a two-phase colloidal system. In this case, PDADMAC with PAA mixes exothermically in the entire range of compositions, and the entropy changes its sign.

ТУРЦИЯ

РЕГИОНАЛЬНЫЕ ПРОЕКТЫ

MASTER'S THESIS

THERMODYNAMICS

POLYMER MIXTURES

POLYELECTROLYTES

POLYDIALLYLDIMETHYLAMMONIUM CHLORIDE

MRI and NMR Investigations of Transport in Soft Materials and Explorations of Electron-Nuclear Interactions for Liquid-State Dynamic Nuclear Polarization

Wang, Xiaoling

28 August 2015

The first part of this dissertation (Chapters 1 to 4) describes the use of magnetic resonance techniques for polymeric material characterizations in solutions, with emphasis on methods utilizing magnetic field gradients - magnetic resonance imaging (MRI) and pulsed-field-gradient (PFG) NMR. The second part (Chapter 5) presents enhancements to dynamic nuclear polarization, an intensity enhancement approach for magnetic resonance techniques. In Chapter 2, I illustrate a characterization method to quantify free polymer chain content in a polymer/DNA complex (polyplex) formulation via one-dimensional proton NMR experiments. This assessment of free polymer quantity has critical impacts on in vivo gene transfection efficiency, cellular uptake, as well as toxicity of polycationic gene delivery vectors. Specifically, I investigated the complexation properties of three different polymeric "theranostic" agents, which combine an imaging functionality on the polymer as well as a DNA/RNA complexation component. These agents are under development to allow real time clinical monitoring of drug delivery and efficacy using MRI. Our NMR method provides simple and quantitative assessment of free and DNA-complexed polymers, including the actual polymer amine to DNA phosphate molar ratio (N/P ratio) within polyplexes. The NMR results are in close agreement with the stoichiometric number of polymer/DNA binding obtained by isothermal titration calorimetry. The noninvasive nature of this method allows broad application to a range of polyelectrolyte coacervates, for understanding and optimizing polyelectrolyte complex formation. Chapter 3 demonstrates a time-resolved MRI approach for measuring diffusion of drug-delivery polymeric nanoparticles on mm to cm scales as well as monitoring nanoparticle concentration distribution in bulk biological hydrogels. Our results show that as the particle size and surface charge become larger, collagen gel at tumor relevant concentration (1.0 wt.%) presents a more significant impediment to the diffusive transport of negatively charged nanoparticles. These results agree well with those obtained by fluorescence spectroscopies (neutral or slightly positively charged diffusing particles) as well as the proposed electrostatic bandpass theory of tumor interstitium (negatively charged particles). This study provides fundamental information for the design of polymeric theranostic vectors and carries implications that would benefit the understanding of nanoparticle transport in solid tumors. Furthermore, this work takes a significant step toward developing quantitative and real time in vivo monitoring of clinical drug delivery using MRI. Chapter 4 addresses the application of PFG-NMR for the determination of weight-average molar mass (Mw) for polyanions that have anti-HIV activity through the measurement of polymer diffusion coefficients in solutions. The effective characterization of molecular weights of polyelectrolytes has been a general and growing problem for the polymer industry, with no clear solutions in sight. In this study, we obtained the molar masses (Mw) for two series of sulfonated copolymers using sodium polystyrene sulfonate samples as molecular weight standards. PFG-NMR has notable advantages over conventional techniques for the characterization of charged polymers and shows great promise for becoming an effective alternative to chromatography methods. Chapter 5 is devoted to experimental and theoretical studies of liquid state dynamic nuclear polarization (DNP) via the Overhauser effect. Based on the adventurous work done by previous Dorn group members, we show that for 1H-nuclide-containing systems, the dipolar DNP enhancement can be significantly improved by decreasing the correlation time of the interaction by utilizing a supercritical fluid (SF CO2) which allows for greater dipolar enhancements at higher magnetic fields. For molecules containing the ubiquitous 13C nuclide, we show that previously unreported sp hybridized (H-C) alkyne systems represented by the phenylacetylene-nitroxide system exhibit very large scalar-dominated enhancements. Furthermore, we show for a wide range of molecular systems that the Fermi contact interaction can be computationally predicted via electron-nuclear hyperfine coupling and correlated with experimental 13C DNP enhancements. For biomedical applications, the enhancement of metabolites in SF CO2 followed by rapid dissolution in water or biological fluids is an attractive approach for future hyperpolarized NMR and MRI applications. Moreover, with the aid of density functional theory calculations, solution state DNP provides a unique approach for studying intermolecular weak bonding interaction of solutes in normal liquids and SF fluids. / Ph. D.

time-resolved microMRI

diffusion

nanoparticles

collagen

polyplex

gene delivery

free polymer quantification

pulsed-field-gradient NMR

molecular weight

polyelectrolytes

Overhauser effect

supercritic

Encapsulation moléculaire de molécules actives hydrophobes par des polymères amphiphiles aléatoires à base de poly(acide diméthylmalique) / Molecular encapsulation of hydrophobic active molecules thanks to random amphiphilic polymers based on poly(dimethylmalic acid)

Schott, Marc-Alexandre

30 November 2012

Nombre de principes actifs rencontrent des problèmes liés à leur faible hydrosolubilité : mauvaise biodisponibilité, métabolisation désactivante, effets secondaires. Pour contourner ce problème, des polyélectrolytes amphiphiles aléatoires ont déjà été étudiés. S'ils ont amélioré la solubilité apparente de composés hydrophobes, ils étaient parallèlement toxiques ou non dégradables, donc non éliminables par l'organisme. Dans ce mémoire, nous présentons la synthèse de différentes malolactones substituées. La copolymérisation anionique par ouverture de cycle de ces lactones a permis d'obtenir une famille de polyanions amphiphiles aléatoires avec un taux d'hydrophobisation variable et contrôlé, et des chaînes latérales, aliphatiques ou aromatique, de différentes longueurs. Ces polymères augmentent la solubilité aqueuse apparente de composés hydrophobes. Lorsque le composé est cationique, une synergie entre interactions hydrophobes et électrostatiques a été mise en évidence. La solubilité apparente de molécules anti-infectieuses a ainsi pu être améliorée de plusieurs ordres de grandeur. Dans les conditions d'une administration intraveineuse (NaCl 9 g.L-1 et pH = 7,5), ces polymères forment préférentiellement des micelles intramoléculaires qui ne sont pas sensibles aux effets de dilution. Un tel système de transport de principes actifs ne produirait donc aucune libération prématurée. Ces polymères étant de plus dégradables, ils pourraient libérer le principe actif et seraient éliminables par l'organisme. Les polymères présentés dans ce manuscrit remplissent les principaux critères physico-chimiques pour former un système de transport de molécules actives. / Lots of drugs meet some problems because of their poor water-solubility : poor bioavailability, desactivating metabolization, side effects. To overcome these problems, some amphiphilic polyelectrolytes have already been studied. They increased the apparent water-solubility of hydrophobic compounds, but were toxic or not degradable, thus could not be eliminated from the body. In this work, we describe the synthesis of various substituted malolactones. Anionic ring opening copolymerization of these lactones yielded random amphiphilic polyanions with varying and controlled hydrophobization ratio and aliphatic and aromatic side chains with different lengths. These polymers increase the apparent water-solubility of hydrophobic compounds. A synergy between hydrophobic and electrostatic interactions has been demonstrated when the compound is cationic. The apparent solubility of anti-infectious drugs could thus be increased by several orders of magnitude. Under intravenous injection conditions (NaCl 9 g.L-1 and pH = 7,5), these polymers form preferentially intramolecular micelles, which are not sensitive to dilution effects. As a consequence, such a drug transport system would yield no premature release. Being also degradable, these polymers could release the drug and be eliminated from the body. They meet all main physico-chemical criteria to become a drug transport system.

Polyesters dégradables

Poly(acide diméthylmalique)

Micelles intramoléculaires

Transport de principes actifs

Random amphiphilic polyelectrolytes

Degradable polyesters

Poly(dimethylmalic acid)

Intramolecular micelles

Drug transport

576

Conception et validation d'un substitut vasculaire naturel, fonctionnalisé par un film multicouche de polyélectrolytes et cellularisé par un endothelium autologue orienté / Conception of a natural vascular substitute, fonctionnalized by a polyelectrolyte multilayer film and cellularized by an autologous endothelium

Paternotte, Estelle

27 September 2010

Les taux élevés de mortalité et de morbidité associés aux maladies vasculaires en font des pathologies dont les conséquences physiopathologiques, chirurgicales et socio-économiques sont d’une importance majeure pour le système de santé. Malgré leurs avantages, la disponibilité limitée des vaisseaux autologues a conduit au développement de prothèses synthétiques. Cependant, leur surface hautement thrombogène limite leur utilisation dans la substitution des vaisseaux de petit calibre (< 6 mm). De ce fait, à cause de leur obstruction précoce, la reconstitution d’une surface luminale proche de l’endothélium natif est incontournable. Pourtant, les revêtements de surface actuellement disponibles possèdent de médiocres qualités de rétention des néo-endothélium lorsqu’ils sont soumis à des contraintes de cisaillement physiologiques. Dans ce travail, nous proposons un substitut vasculaire de petit calibre endothélialisé réalisé à partir de trois éléments : 1) une matrice préparée à partir d’une artère ombilicale désendothélialisée, 2) un recouvrement de surface innovant constitué du film multicouche de polyélectrolytes (MPE) (PAH-PSS)3-PAH, et 3) un néo-endothélium constitué de cellules endothéliales matures ou progénitrices. Les études in vitro menées sur ces substituts ont montré que la formation, la rétention sous contraintes de cisaillement et la fonctionnalité du néoendothélium élaboré sur la surface luminale étaient améliorées par le film MPE. L’implantation du substitut par pontage termino-latéral sur le lapin a montré que le cahier des charges imputé aux substituts de petit calibre était rempli, principalement en termes de perméabilité et de diamètre, mais aussi de résistance à la suture et aux infections. En conclusion, le film MPE favorise le développement d’un substitut vasculaire de petit diamètre perméable à « long » terme et qui pourrait répondre aux exigences des chirurgiens / Vascular diseases with their high rate of mortality and morbidity belong to the pathologies involving important socio-economic factors for health system. Despite the advantages of autografts, the limited availability of autologous vessels has led to the development of synthetic prostheses. However, their high thrombogenic surface limits their use as small calibre vascular substitutes (< 6 mm). To prevent narrowing of small diameter vascular grafts, the reconstruction of a luminal surface close to the native endothelium is essential. However, the retention of the neo-endothelium subjected to shear stress is poor on the coatings currently available. In this work, we developed a small calibre endothelialized vascular substitute thanks to three elements: 1) a natural matrix prepared from umbilical artery, 2) an innovative coating based on the polyelectrolytes multilayer film (PEM) (PAH-PSS)3-PAH, and 3) used for cell culture of mature or progenitor endothelial cells. In vitro studies have shown that the formation, the retention under shear stress and the endothelial function of the neoendothelium on the luminal surface were improved by PEM film. The anastomosis of this substitute on rabbits has shown that the specifications essential to small calibre vascular grafts were reached, mainly in terms of permeability and diameter but also of resistance to suture and infections. In conclusion, PEM films helped us to develop a small diameter vascular substitute with long term patency

Ingénierie vasculaire

Substitut vasculaire de petit calibre

Film multicouche de polyélectrolytes

Cellules endothéliales matures

Progéniteurs endothéliaux

Contraintes de cisaillement

Pontage carotidien

Vascular engineering

Small calibre vascular graft

Polyelectrolytes multilayer films

Endothelial cells

Progenitor endothelial cells

Shear stress

Vascular by-pass

Production and characterisation of self-crosslinked chitosan-carrageenan polyelectrolyte complexes

Al-Zebari, Nawar

January 2017

Macromolecular biomaterials often require covalent crosslinking to achieve adequate stability and mechanical strength for their given application. However, the use of auxiliary chemicals may be associated with long-term toxicity in the body. Oppositely-charged polyelectrolytes (PEs) have the advantage that they can self-crosslink electrostatically and those derived from marine organisms are an inexpensive alternative to glycosaminoglycans present in the extracellular matrix of human tissues. A range of different combinations of PEs and preparation conditions have been reported in the literature. However, although there has been some work on complex formation between chitosan (CS) and carrageenan (CRG), much of the work undertaken has ignored the effect of pH on the consequent physicochemical properties of self-crosslinked polyelectrolyte complex (PEC) gels, films and scaffolds. Chitosan is a positively-charged polysaccharide with NH3+ side groups derived from shrimp shells and, carrageenan is a negatively-charged polysaccharide with OSO3- side groups derived from red seaweed. These abundant polysaccharides possess advantageous properties such as biodegradability and low toxicity. However, at present, there is no clear consensus on the cell binding properties of CS and CRG or CS-CRG PEC materials. The aim of this study was to explore the properties of crosslinker-free PEC gels, solvent-cast PEC films and freeze-dried PEC scaffolds based on CS and CRG precursors for medical applications. The objective was to characterise the effect of pH of the production conditions on the physicochemical and biological properties of CS-CRG PECs. Experimental work focused on the interaction between PEs, the composition of PECs, the rheological properties of PEC gels and the mechanical properties of PEC films and scaffolds. In addition, cell and protein attachment to the PEC films was assessed to determine their interactions in a biological environment. For biomedical applications, these materials should ideally be stable when produced such that they can be processed to form either a film or a scaffold and have mechanical properties comparable to those of collagenous soft tissues. FTIR was used to confirm PEC formation. Zeta potential measurements indicated that the PECs produced at pH 2-6 had a high strength of electrostatic interaction with the highest occurring at pH 4-5. This resulted in stronger intra-crosslinking in the PEC gels which led to the formation of higher yield, solid content, viscosity and fibre content in PEC gels. The weaker interaction at pH 7-12 resulted in higher levels of CS incorporated into the complex and the formation of inter-crosslinking through entanglements between PEC units. This resulted in the production of strong and stiff PEC films and scaffolds appropriate for soft tissue implants. The PECs prepared at pH 7.4 and 9 also exhibited low swelling and mass loss, which was thought to be due to the high CS content and entanglements. From the range of samples tested, the PECs produced at pH 7.4 appeared to show the optimum combination of yield, stability and homogeneity for soft tissue implants. Biological studies were performed on CS, CRG and PECs prepared at pH 3, 5, 7.4 and 9. All of the PE and PEC films were found to be non-cytotoxic. When the response of three different cell types and a high binding affinity protein (tropoelastin) was evaluated; it was found that the CS-CRG PEC films displayed anti-adhesive properties. Based on these experimental observations and previous studies, a mechanistic model of the anti-adhesive behaviour of PEC surfaces was proposed. It was therefore concluded that the CS-CRG PECs produced might be suitable for non-biofouling applications.

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