Global ETD Search

51	Microgéis termo-responsivos preparados a partir dos polímeros do amido Leite, Daiani Canabarro January 2017 (has links) Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure. Amilopectina Amilose Nanoparticulas Amido Polimeros : Termodinamica Starch polymers Phase transition temperature Microgel N-isopropylacrylamide Thermo-responsive polymer Starch nanoparticles Amylopectin Amylose
52	Computer Simulations of Polymer Gels : Structure, Dynamics, and Deformation Kamerlin, Natasha January 2017 (has links) This thesis presents the results of computer simulation studies of the structure, dynamics, and deformation of cross-linked polymer gels. Obtaining a fundamental understanding of the interrelation between the detailed structure and the properties of polymer gels is a challenge and a key issue towards designing materials for specific purposes. A new off-lattice method for constructing a closed network is presented that is free from defects, such as looping chains and dangling ends. Using these model networks in Brownian dynamics simulations, I show results for the structure and dynamics of bulk gels and describe a novel approach using spherical boundary conditions as an alternative to the periodic boundary conditions commonly used in simulations. This algorithm was also applied for simulating the diffusion of tracer particles within a static and dynamic network, to illustrate the quantitative difference and importance of including network mobility for large particles, as dynamic chains facilitate the escape of particles that become entrapped. I further investigate two technologically relevant properties of polymer gels: their stimuli-responsive behaviour and their mechanical properties. The collapse of core-shell nanogels was studied for a range of parameters, including the cross-linking degree and shell thickness. Two distinct regimes of gel collapse could be observed, with a rapid formation of small clusters followed by a coarsening stage. It is shown that in some cases, a collapsing shell may lead to an inversion of the core-shell particle which exposes the core polymer chains to the environment. This thesis also explores the deformation of bimodal gels consisting of both short and long chains, subject to uniaxial elongation, with the aim to understand the role of both network composition as well as structural heterogeneity on the mechanical response and the reinforcement mechanism of these materials. It is shown that a bimodal molecular weight distribution alone is sufficient to strongly alter the mechanical properties of networks compared to the corresponding unimodal networks with the same number-average chain length. Furthermore, it is shown that heterogeneities in the form of high-density short-chain clusters affect the mechanical properties relative to a homogeneous network, primarily by providing extensibility. computer simulations Brownian dynamics polymer gel microgel spherical boundary conditions hypersphere core-shell deswelling mechanical properties uniaxial elongation Physical Chemistry Fysikalisk kemi Polymer Chemistry Polymerkemi
53	N-Vinylcaprolactam based Bulk and Microgels: Synthesis, Structural Formation and Characterization by Dynamic Light Scattering Boyko, Volodymyr 08 October 2004 (has links) The light scattering methods were used for characterization of properties and formation of networks of different dimension, based on N-vinylcaprolactam (VCL). Formation of PVCL microgels in presence of poly(vinyl alcohol) as stabilizer was studied. Size of resulting microgels strongly depends on the temperature and heating rate: interparticle aggregation was observed during slow heating and intraparticle collapse during fast heating. Angular dependence of measured diffusion coefficient on the angle of observation was studied for the microgel in the swollen, shrunken and aggregated states. Thermo-sensitive microgels based on N-vinylcaprolactam and acetoacetoxyethyl methacrylate were prepared under surfactant free conditions. The presence of internal part with low thermo-sensitivity and highly thermo-sensitive outer part of the particle (the core-shell structure of microgel) was deduced from static and dynamic light scattering experiments. Results obtained from combined SLS and DLS show the change of conformation from &quot;swollen&quot; soft sphere to compact shrunken &quot;hard sphere&quot;. Thermo-sensitive microgel based on N-vinylcaprolactam and N-vinylpyrrolidone was used for investigation of the internal modes in microgel dispersion in the wide range of qRg values. Two internal motions and translation diffusion were observed in the asymptotic range. Angular dependence of the normalized diffusion coefficient showed power law behavior in this range. The experimentally determined value of exponent n = 0.96 was in good agreement with the value predicted for ZIMM limit for polymer chains with hydrodynamic interaction. The reduced first cumulant Ã*(q) reached a constant value in the range of large qRg values. Appearance of plateau value indicates ZIMM limit of hydrodynamic interaction but experimental value was much lower than the theoretically predicted plateau value for linear chains in good solution. 3,3?-(ethane-1,1-diyl)bis(1-vinyl-2-pyrrolidone) was used as a cross-linker of VCL in solution by radical polymerization. The network formation was investigated by dynamic light scattering. It was shown, that monitoring of the light scattered intensity in all cases is quite sensitive to detect the gelation threshold even in the presence of very low amount of cross-linker. The power law of time correlation function at the gel point is a sufficient but not a necessary condition for critical gelation. The exponent calculated from power law depends on cross-linker concentration and can be attributed to the degree of branching. Critical exponents obtained at the gel point by DLS and rheology for hydrogel system based on VCL and hydroxyethyl methacrylate were compared. The theoretically predicted equality of exponents from these methods was found as not valid at least for this studied system. info:eu-repo/classification/ddc/540 ddc:540
54	Dispersionen für den Korrosionsschutz von Aluminium: Synthese, Charakterisierung und Anwendung Henke, Axel 27 November 2000 (has links) The adsorption and organization of reactive microgels has been investigated on technical aluminium. By means of a two-step emulsion polymerisation with phosphate substituted monomer we obtain polymeric nano-particles with phosphate groups on the surface. In a first step cross-linked butyl acrylate/styrene particles were formed. In a second step a mixture of functionalised acrylate and butyl acrylate/styrene was added to the system. In this way, the composite particles were obtained. Particle size and size distribution were measured by F-FFF and light scattering methods. For phosphate functionalised dispersions, it was possible to show the distribution of P-species around particles by energy dispersive TEM easurements. These nano-particles adsorb spontaneously onto aluminium surfaces from aqeous dispersion. They form well packed layers, which have been proved by SEM measurements. The properties of the adsorbed microgel layers were confirmed by industrial linked adhesion and corrosion tests. Panels with adsorbed phosphate funczionalised particles have an excellent corrosion inhibition effect. info:eu-repo/classification/ddc/30 ddc:30
55	Funktionalisierte Polymerkomposite auf Basis von Poly(3,4-ethylendioxythiophen) und Gold Hain, Jessica 15 April 2008 (has links) Poly(3,4-ethylenedioxythiophene), PEDOT, belongs to the group of conducting polymers and is characterized by its high stability, a moderate band gap and its optical transparency in the conductive state. A large disadvantage of conducting polymers, and also PEDOT, is their poor solubility. One way to achieve processible materials is the synthesis of colloidal particles. Thus, this work focuses on the development of conductive particles by preparing composite structures. Polymeric colloids like latex particles and microgels were used as templates for the oxidative polymerization of EDOT. Depending on template structure completely different composite morphologies with variable properties were obtained. It was found that modification with PEDOT did not only cause conductive particles for application as humidity sensor materials, but also candidates for further functionalization with gold nanoparticles (Au-NPs). Due to a multi-stage synthesis route it was possible to achieve polystyrene(core)-PEDOT(shell)-particles decored with Au-NPs. Microgels acting as “micro reactors” for the incorporation of PEDOT and Au-NPs were also used for preparing multifunctional composites for catalytic applications. / Poly(3,4-ethylendioxythiophen), PEDOT, gehört zur Gruppe der leitfähigen Polymere und zeichnet sich durch seine hohe Stabilität, eine moderate Bandlücke und seine optische Transparenz im dotierten Zustand aus. Ein Nachteil leitfähiger Polymere, wie auch von PEDOT, ist deren schlechte Löslichkeit. Die Synthese kolloidaler Partikel bietet jedoch eine Möglichkeit dieses Problem zu umgehen. In diesem Zusammenhang richtete sich der Fokus dieser Arbeit auf die Darstellung leitfähiger Partikel in Form von Kompositstrukturen. Polymerkolloide, wie Latex- und Mikrogelpartikel, sind als Template eingesetzt worden, in deren Gegenwart PEDOT durch eine oxidative Polymerisation synthetisiert wurde. In Abhängigkeit von der Struktur des Templats sind unterschiedliche Kompositmorphologien mit steuerbaren Eigenschaften erhalten worden. Auf diese Weise wurden neben Materialien für die Feuchtigkeitssensorik leitfähige Kompositpartikel hergestellt, die zusätzlich mit Gold-Nanopartikeln (Au-NP) funktionalisiert werden konnten. Durch ein mehrstufiges Syntheseverfahren sind somit Polystyrol(Kern)-PEDOT(Schale)-Partikel mit Au-NP-funktionalisierter Oberfläche synthetisiert worden. Mikrogelpartikel, die als „Mikroreaktoren“ für die Inkorporation von PEDOT- und Au-NP dienten, wurden ebenfalls eingesetzt, um multifunktionale Komposite mit katalytischen Eigenschaften herzustellen. info:eu-repo/classification/ddc/540 ddc:540
56	Polymerpartikel für biomedizinische Anwendungen Häntzschel, Nadine 04 April 2008 (has links) Gegenstand dieser Arbeit ist die Herstellung funktioneller Polymerpartikel und deren Nutzung für biomedizinische Applikationen. Die Anwendungsgebiete der resultierenden Hybridmaterialien reichen vom Einsatz als Kontrastmittel in bildgebenden Verfahren der medizinischen Diagnostik über die Verwendung als Antimikrobium bis hin zum Einsatz als „Werkzeug“ zur Zellisolierung und aktivierung. Dazu wurden kompakte Latexpartikel und sensitive, poröse Mikrogelpartikel mittels emulgatorfreier Heterophasenpolymerisation synthetisiert. Als funktionelles Monomer wurde Glycidylmethacrylat verwendet, über dessen reaktive Epoxygruppen anschließend weitere Moleküle angebunden werden können. Die Funktionalisierung der Polymerpartikel erfolgte einerseits mit anorganischen Nanopartikeln (dotierte Lanthanfluorid-Nanopartikel, Gold- und Silbernanopartikel) und andererseits mit Biomolekülen wie Nukleotiden und Antikörpern. Einige Verwendungsgebiete, wie die Stimulierung von Memory-T-Zellen mit Antikörper-Polymer-Konjugaten oder der Einsatz der Silberkomposite aufgrund ihrer antimikrobiellen Wirkung, wurden näher untersucht. / The aim of this work was the synthesis of functional polymeric particles and their use for biomedical purposes. The application areas of the resulting hybrid materials range from contrast agents in medical diagnostics and usage due to antimicrobial properties to “tools” for cell isolation and activation. Compact core-shell particles and porous microgel particles were prepared by surfactant-free heterophase polymerization in water. All particles contain glycidyl methacrylate whose epoxy groups are capable to bind other molecules covalently. On the one hand, polymeric particles were functionalized with inorganic nanoparticles (doped lanthanum fluoride nanoparticles, gold and silver nanopariticles) and on the other hand with biomolecules such as nucleotides and antibodies. Selected application fields like the stimulation of memory T-cells with polymer-antibody-conjugates or the use of the silver composites due to their antimicrobial activity were investigated in detail. info:eu-repo/classification/ddc/540 ddc:540
57	Effet d'ultrasons de puissance sur les matériaux mous : vers des matériaux "acousto-rhéologiques" / Effect of high intensity ultrasound on soft materials : towards « rheo-acoustical » materials Lidon, Pierre 08 July 2016 (has links) Les méthodes d'imagerie et de vélocimétrie ultrasonores ont prouvé leur efficacité pour étudier des matériaux divers. À haute intensité, il est connu que les ultrasons exercent des forces stationnaires dans les fluides newtoniens, par le biais d'effets non linéaires comme la pression de radiation acoustique. Néanmoins, ces effets n'ont encore jamais été exploités d'un point de vue fondamental dans le contexte de la physique des matériaux mous. L'objet de cette thèse est d'exploiter l'interaction d'ultrasons de puissance avec des matériaux bloqués afin de sonder activement, voire d'influencer leurs propriétés mécaniques. Nous proposons tout d'abord une méthode de microrhéologie active : la « mésorhéologie acoustique ». En analysant le mouvement d'un intrus sous l'effet de la pression de radiation acoustique, nous caractérisons localement la rhéologie du matériau étudié. Nous mettons cette technique en œuvre avec un fluide à seuil simple : un microgel de carbopol. Nous exploitons les résultats obtenus à la lumière d'une caractérisation rhéologique poussée du comportement de ce matériau en dessous de son seuil d'écoulement et proposons diverses pistes d'amélioration du dispositif.Ensuite, nous décrivons la mise en écoulement d'un empilement granulaire immergé par des ultrasons intenses focalisés et comparons les observations aux résultats de simulations de dynamique moléculaire. La transition de fluidification observée car l'injection d'énergie y est discontinue. Elle est intermittente et hystérétique, propriétés reproduites par des simulations numériques et dont un modèle phénoménologique simple permet de rendre compte.Enfin, en remplaçant le plan d'un rhéomètre classique par un transducteur ultrasonore, nous mesurons l'effet de vibrations à haute fréquence sur les propriétés mécaniques d'un gel colloïdal fragile de noir de carbone. Nous observons un effet significatif et potentiellement irréversible des ultrasons sur le module élastique et sur la mise en écoulement de ce système. Les vibrations semblent favoriser le glissement du gel aux parois mais il semble toutefois qu'elles induisent également des changements en volume dans l'échantillon. / Ultrasonic imaging and velocimetry has been proved to be very efficient methods to study various materials. At high intensity, ultrasonic waves are known to exert steady forces in newtonian fluid through nonlinear effects like the acoustic radiation pressure. However those effects have never been used in fundamental studies of the physics of soft materials. This thesis aims at exploiting the interaction between high intensity ultrasound and soft jammed materials to probe actively and even modify their mechanical properties.We first introduce an alternative technique for active microrheology we called « acoustic mesorheology ». By analyzing the motion of an intruder under the acoustic radiation pressure we characterize locally the rheology of the system under study. We test this technique on a simple yield stress fluid, namely a carbopol microgel. We compare the results with those obtained by standard rheology measurements of the behaviour of this gel under its yield stress.Then we describe the fluidization of an immersed granular packing by high intensity focused ultrasound. We compare our observations with the results of molecular dynamics simulations. The obtained fluidization is original as the injection of energy is discontinuous in time. It is hysteretic and intermittent and those properties are well captures by both simulations and a phenomenological model.Finally, we replace the plane of a standard cone-plate rheometer by an ultrasonic transducer. This allows us to characterize the effect of high frequency vibrations on the rheology of a fragile carbon black gel. We observe a significant and eventually irreversible effect of ultrasound on the elastic modulus and on the yielding of the system. Vibrations are shown to favor wall slip but seem to induce changes in the volume of the sample though. Ultrasons de puissance Matière molle Pression de radiation acoustique Microrhéologie active Fluage Microgel de carbopol Fluidification Milieux granulaires Dynamique moléculaire Gels de noir de carbone High intensity ultrasound Soft matter Acoustic radiation pressure Active microrheology Creep Carbopol microgel Fluidization Granular materials Molecular dynamics Carbon black gels
58	Phase Phenomena in Polymer Networks : Empirical Studies on the Influence of Hydrophobicity, Charge Density and Crosslinks on Macroion-Induced Phase Transitions in Polyelectrolyte Gels Andersson, Martin January 2011 (has links) The thesis concerns polyelectrolyte gels in contact with oppositely charged proteins and surfactant micelles, and includes of four papers (I-IV). In paper I confocal Raman spectroscopy was introduced as a method to trace micelles and investigate the structure of gel-surfactant complexes, in phase separated gel spheres. In paper II, the binding of surfactants to microspheres (~50-100 µm) was investigated by means of a micromanipulator-assisted microscopy method. The two surfactants were found to display qualitative difference respect to degree of swelling, surfactant distribution in the gels, and the difference is discussed in terms of absence/presence of hydrophobic attraction to the polyelectrolyte gel network. Kinetics of volume change in gels were analyzed. Aggregation numbers of micelles in polystyrenesulfonate (PSS) solutions, obtained from fluorescence quenching measurements, are presented. In paper III, phase behaviour, protein assembly and diffusion, was studied in PSS gel microspheres. Interpretation of results was aided by measurements of osmotic swelling of individual gel networks, and by combining the results with studies of protein diffusion in macroscopic (cm-sized) gel spheres. Complexes formed were further analyzed with small angle x-ray spectroscopy. In paper IV phase behaviour of mixed ionic/nonionic surfactant micelles is investigated in cm-sized gel spheres. The coexistence of three phases, the formation of dense shells in the bulk of the gels and other phenomena are described for the first time, and the results are presented along with discussion on the charge-density of spherical micelles and of network induced hysteresis effects in gels. The composition and microstructure of phases are investigated by confocal Raman spectroscopy and small-angle x-ray scattering respectively. The results are interpreted with aid of highly detailed theoretical model calculations. Gel microgel microsphere polystyrenesulfonate polyacrylate polyacrylicacid DoTAB DoTAC CTAB CTAC network polyelectrolyte complex salt self assembly phase behaviour hysteresis thermodynamic core-shell lysozyme cytochrome c microscopy micromanipulator elastomer elastic protein surfactant phase behaviour sorting PHARMACY FARMACI Physical chemistry Fysikalisk kemi
59	Novel Antipsychotic Drug Carriers: The Development of Nanoparticle and Microgel Drug Carriers for Antipsychotic Delivery in the Treatment of Schizophrenia Piazza, Justin E. 10 1900 (has links) <p>Lectin-functionalized, Poly [oligo(ethylene glycol) methyl ether methacrylate] (<em>POEGMA</em>) loaded with 3(R)-[(2(S)-pyrrolidinylcarbonyl)amino]-2-oxo-1-pyrrolidineacetamide (PAOPA) and poly(ethylene glycol)–block-poly(D,L-lactic-co-glycolic acid) (PEG-PLGA) nanoparticles loaded with haloperidol were prepared with narrow size distributions and sizes < 135 nm. The microgels and nanoparticles exhibited high <em>Solanum tuberosum </em>lectin (STL) conjugation efficiencies, encapsulation efficiencies, and drug loading capacities. The <em>in vitro</em> release of PAOPA and haloperidol was slow in physiological conditions over 96 hours, demonstrating minimal drug leakage and the potential for efficient drug transport to the targeted brain tissue. POAPA, POEGMA and the STL-functionalized POEGMA microgels were found to be non-toxic in both cell lines, indicating that they would not be toxic when administered intranasally or when they reach the brain. The nasal epithelial cell uptake of rhodamine-labelled microgels was higher in cells when the STL-functionalization was present. All haloperidol-loaded nanoparticle formulations were found to be highly effective at inducing catalepsy, while intranasal administration of STL-functionalized nanoparticles using the intranasal spray device increased the brain tissue haloperidol concentrations by 2-3.5 fold compared to STL-functionalized particles administered intranasally with a pipette. For the first time, brain tissue concentrations of rhodamine-labelled microgels confirmed that microgels are capable of passing the blood-brain barrier and that this uptake is size dependent. These formulations demonstrate promise in the reduction of the drug dose necessary to produce a therapeutic effect with antipsychotic drugs for the treatment of schizophrenia using a non-invasive route of administration.</p> / Master of Science (MSc) nanoparticle microgel antipsychotic allosteric modulator PAOPA Amino Acids, Peptides, and Proteins Biochemistry Biomaterials Cell Biology Medicinal Chemistry and Pharmaceutics Molecular and Cellular Neuroscience Molecular Biology Nanomedicine Nervous System Diseases Pharmaceutics and Drug Design Polymer Science Psychiatric and Mental Health Toxicology Amino Acids, Peptides, and Proteins

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