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111	Probing the adsorption of polymer depressants on hydrophobic surfaces using the quartz crystal microbalance Sedeva, Iliana January 2010 (has links) The hydrophobicity of a surface is an important property in many areas of science and engineering. This is especially the case in mineral processing, where differences in surface hydrophobicity lie at the heart of the separation process of flotation. Chemicals are used to increase and decrease the natural hydrophobicity of minerals to attain a better separation between valuable and worthless material. Polymers are often used to reduce mineral surface hydrophobicity. Decades of empirically based decision making have produced a list of effective depressants. However the detailed study of how these polymer depressants affect surface hydrophobicity and mineral recovery lags behind applied investigations. The aim of this thesis was to study the adsorption of commonly used depressants on model surfaces and to interrogate the action of these polymers in reducing surface hydrophobicity. We have modelled the degree of hydrophobicity of common minerals in order to study polymer depressants with methods not commonly used in studies of surface characterisation in flotation. The model surfaces (self-assembled monolayers, SAMs) allowed us to use the quartz crystal microbalance with dissipation monitoring (QCM-D) to study the adsorption of polymers. The QCM-D can be used to obtain adsorption isotherms, adsorption kinetics, water content of adsorbed layers, and information on the conformation of the adsorbed polymer. The results from the QCM-D were correlated with the contact angle data from the captive bubble measurements, with which we assessed the hydrophobicity of the surface before and after polymer adsorption. Three of the polymers layers were probed with dynamic dewetting studies, in order to test other modes of depressant action. Three types of polymers were studied - a polyacrylamide (Polymer-H), a polyelectrolyte CMC (carboxymethyl cellulose) and a group of dextrins (Dextrin-TY, a phenyl succinate substituted dextrin (PS Dextrin) and a styrene oxide substituted dextrin (SO Dextrin)). These polymers are commonly used or have potential to be used in the depression of talc and graphite. Polymer-H was used to investigate the hydrophobic bonding between a non-ionic polymer depressant and chemically inert and non charged surfaces by probing the influence of substrate hydrophobicity on polymer adsorption and reduction of contact angle. Three different model surfaces were used (mixed self-assembled 0.5 SAM, 0.7 SAM or single self-assembled 1.0 SAM monolayers) with advancing contact angles between 75?? and 119??. The study of Polymer-H found that the substrate hydrophobicity is an important factor in adsorption of this polymer and the change in contact angle upon adsorption depends on adsorbed amount. The effectiveness of Polymer-H to reduce surface hydrophobicity was established to correlate with its conformation and morphology. CMC was investigated to find out how a stimulus responsive polymer depressant can be used in flotation. It was established that the adsorbed amount and rate of adsorption of CMC increase with decreasing of pH or increasing of ionic strength. It was shown that the surface hydrophobicity of a CMC pre-adsorbed layer changes with the environment and these alterations are fully reversible. A switch of ionic strength (from 10-2 M KCl to 10-1 M KCl) caused partial dehydration of the adsorbed layer and a decrease of the receding contact angle by 20??. A pH switch (pH = 9 to pH = 3) resulted in a 40?? change in receding contact angle. The CMC investigation showed that the use of a stimulus responsive polymer presents opportunities for exploiting solution conditions as a means to effect a better mineral separation in flotation The adsorption of three dextrin-based polymers on a model hydrophobic surface has been characterized using the quartz crystal microbalance with dissipation monitoring (QCM-D). The three polymers (one standard dextrin and two dextrins with different aromatic group substitutions) exhibited varying affinities and capacity for adsorption on the hydrophobic substrate. The effect of the three polymers on the static contact angle of the surface was studied using captive bubble contact angle measurements. The three polymers were seen to reduce the receding contact angle by similar amounts (approximately 14 degrees) in spite of having varying adsorbed amounts and differences in adsorbed layer water content. Although no differences were observed in the ability of the polymers to reduce the static contact angle, measurements of the dewetting dynamics between a rising air bubble and the polymer covered substrate yielded stark differences between the polymers, with one polymer slowing the dewetting dynamics by an order of magnitude more than the other two polymers. The differences in dewetting behaviour correlate with the adsorbed layer characteristics determined by QCM-D. / Thesis (PhD)--University of South Australia, 2010 Hydrophobic surfaces Polymer solutions Adsorption 249901 Biophysics 249903 Instruments and Techniques 250103 Colloid and Surface Chemistry 250204 Bioinorganic Chemistry 260101 Mineralogy and Crystallography QCM-D AFM polymer depressant
112	Assemblages 2D de l'Annexine A5 : Applications biotechnologiques & Aspects fonctionnels Berat, Rémi 12 December 2007 (has links) (PDF) L'Annexine A5 (Anx5) est une protéine de la famille des annexines qui présente la propriété de s'organiser à la surface des bicouches lipidiques en trimères et en assemblages bidimensionnels (2D) de trimères. Ce travail de thèse concerne le développement d'applications biotechnologiques des assemblages 2D d'Anx5 ainsi qu'une étude des propriétés fonctionnelles de ces assemblages. Ces travaux ont été réalisés principalement à l'aide des méthodes de la microbalance à cristal de quartz avec mesure de dissipation (QCM-D) et de la microscopie à force atomique (AFM). <br />La première partie de cette thèse concerne le développement de plates-formes d'ancrage basées sur des assemblages 2D de protéines dérivées de l'Anx5. Des complexes covalents entre l'Anx5 et des peptides d'adhésion cellulaire pour la réalisation de plates-formes d'ancrage de cellules. Des protéines de fusion entre l'Anx5 et un fragment de la protéine A ont d'autre part servi au développement de plates-formes 2D pour l'immobilisation contrôlée d'anticorps et de protéines. <br />La seconde partie de cette thèse concerne l'étude des propriétés fonctionnelles des assemblages 2D d'Anx5. L'étude de l'interaction d'un anticorps anti-phospholipide avec les assemblages 2D d'Anx5 montre que cet anticorps ne perturbe pas l'organisation 2D de l'Anx5. La seconde étude concernant l'influence des assemblages 2D de l'Anx5 sur la dynamique des bicouches lipidiques établie une corrélation entre la formation de trimères et le ralentissement de la dynamique des membranes.<br />Ces travaux contribuent à notre compréhension des propriétés des assemblages 2D d'Anx5 et permettent d'envisager le développement de biocapteurs pour cellules ou molécules. Annexine A5 Bicouche lipidique supportée (SLB) Microscopie à force atomique (AFM) biocapteur adhésion cellulaire syndrome anti-phospholipide
113	Elaboration de Nouveaux Matériaux d'Electrodes obtenus par Autoassemblage de Polyélectrolytes, Nanoparticules et Biomolécules : Etudes physico-chimiques et applications. Fatisson, Julien 25 October 2005 (has links) (PDF) La thèse décrit la caractérisation physico-chimique et les applications électroanalytiques de nouveaux matériaux nanocomposites, déposés sur des surfaces d'électrode par autoassemblage électrostatique de polyélectrolytes (PE), d'enzymes et de nanoparticules d'or (NP).<br />La croissance de ces films multicouches fut suivie in situ par spectroscopie et microgravimétrie. L'électrochimie a permis de quantifier le processus de transfert d'électron, la perméabilité des films et la cinétique électroenzymatique. Des relations structure-propriétés furent établies par modélisation cinétique et structurale.<br />La glucose oxydase et la polyphénol oxydase furent assemblées sur des électrodes d'or et de carbone vitreux avec le polydiallyldimethylammonium et le chitosane. L'assemblage de NP et de PE redox, à base de complexe d'osmium ou de viologène, conduit à des films nanocomposites dont les propriétés de conduction électronique furent caractérisées et appliquées au développement de transducteurs. Monocouche autoassemblée films multicouches autoassemblage électrostatique nanoparticules d'or polyélectrolytes redox multicouches d'enzymes électrodes modifiées électrochimie modélisation cinétique transfert d'électron perméabilité de la membrane
114	A novel biotinylated surface designed for QCM-D applications Nilebäck, Erik January 2009 (has links) <p> </p><p>Control of protein immobilization at sensor surfaces is of great interest within various scientific fields, since it enables studies of specific biomolecular interactions. To achieve this, one must be able to immobilize proteins with retained native structure, while minimizing non-specific protein binding. The high affinity interaction between streptavidin (SA) and biotin is extensively used as a linker between a surface, where SA is immobilized, and the (biotinylated) molecule of interest. Self- assembled monolayers (SAMs) of poly- and oligo ethylene glycol (PEG and OEG) derivatives have been proven in literature to minimize non-specific protein binding, and biotin-exposing SAMs have been shown efficient for immobilization of SA.</p><p>The aim of this master's thesis project was to develop biotinylated gold surfaces for quartz crystal microbalance with dissipation monitoring (QCM-D) applications through the self-assembly of mixed monolayers of thiolated OEG (or PEG) derivatives with or without a terminal biotin head group. For this, different thiol compounds were to be compared and evaluated. For the systems under study, the required biotin density for maximum specific SA immobilization was to be established, while keeping the non-specific serum adsorption at a minimum. Model experiments with biotinylated proteins immobilized to the SA-functionalized surfaces were to be performed to evaluate the possibilities for commercialization.</p><p>A protocol for the preparation of a novel biotinylated surface was developed based on the immersion of gold substrates in an ethanolic incubation solution of dithiols with OEG chains (SS-OEG and SS-OEG-biotin, 99:1) and found to give reproducible results with respect to low non-specific protein binding and immobilization of a monolayer of SA. The modified surfaces allowed for subsequent immobilization of biotinylated bovine serum albumin (bBSA) and biotinylated plasminogen (bPLG). PLG was the subject of a challenging case study, using a combination of QCM-D and surface plasmon resonance (SPR), where the immobilized protein was subjected to low molecular weight ligands that were believed to induce conformational changes. The high control of the surface chemistry allowed for the interpretation of the increased dissipation shift upon ligand binding in terms of conformational changes.</p><p>An obstacle before commercialization of the described biotinylated surfaces is that they do not seem stable for storage > 7 days. The reasons for this have to be investigated further.</p> QCM-D Self-assembled monolayer SAM thiol ethylene glycol OEG PEG biosensor surface chemistry biotin streptavidin ellipsometry contact angle goniometry surface plasmon resonance SPR impedance spectroscopy IS sensor surface Molecular physics Molekylfysik
115	Microfluidics in Surface Modified PDMS : Towards Miniaturized Diagnostic Tools Thorslund, Sara January 2006 (has links) <p>There is a strong trend in fabricating <i>miniaturized total analytical systems</i>, µTAS, for various biochemical and cell biology applications. These miniaturized systems could e.g. gain better separation performances, be faster, consume less expensive reagents and be used for studies that are difficult to access in the macro world. Disposable µTAS eliminate the risk of carry-over and can be fabricated to a low cost.</p><p>This work focused on the development of µTAS modules with the intentional use for miniaturized diagnostics. Modules for blood separation, desalting, enrichment, separation and ESI-MS detection were successfully fabricated. Surface coatings were additionally developed and evaluated for applications in µTAS with complex biological samples. The first heparin coating could be easily immobilized in a one-step-process, whereas the second heparin coating was aimed to form a hydrophilic surface that was able to draw blood or plasma samples into a microfluidic system by capillary forces. </p><p>The last mentioned heparin surface was further utilized when developing a chip-based sensor for performing CD4-count in human blood, an important marker to determine the stage of an HIV-infection.</p><p>All devices in this work were fabricated in PDMS, an elastomeric polymer with the advantage of rapid and less expensive prototyping of the microfabricated master. It was shown that PDMS could be considered as the material of choice for future commercial µTAS. The devices were intentionally produced using a low grade of fabrication complexity. It was however demonstrated that even with low complexity, it is possible to integrate several functional chip modules into a single microfluidic device.</p> Materials science µTAS micro total analysis system PDMS poly(dimethylsiloxane) microfluidics heparin blood filtration on-chip ESI-MS desalting QCM-D biocompatible CD4 capillary flow lab-on-chip microfabrication enrichment point-of-care hydrophilic oxidation Materialvetenskap
116	Polyelectrolytes : Bottle-Brush Architectures and Association with Surfactants Naderi, Ali January 2008 (has links) This thesis has the dual purpose of raising awareness of the importance of the mixing protocol on the end products of polyelectrolyte-oppositely charged surfactant systems, and to contribute to a better understanding of the properties of bottle-brush polyelectrolytes when adsorbed onto interfaces. In the first part of this thesis work, the effects of the mixing protocol and the mixing procedure on formed polyelectrolyte-oppositely charged surfactant aggregates were investigated. It was shown that the initial properties of the aggregates were highly dependent on the mixing parameters, and that the difference between the resulting aggregates persisted for long periods of time. The second part of the studies was devoted to the surface properties of a series of bottle-brush polyelectrolytes made of charged segments and segments bearing poly(ethylene oxide) side chains; particular attention was paid to the effect of side chain to charge density ratio of the polyelectrolytes. It was shown that the adsorbed mass of the polyelectrolytes, and the corresponding number of poly(ethylene oxide) bearing segments at the interface, went through a maximum as the charge density of the polyelectrolyte was increased. Also, it was found that bottle-brush polyelectrolyte layers were desorbed quite easily when subjected to salt solutions. This observation was rationalized by the unfavourable excluded volume interactions between the side chains and the entropic penalty of confining them at an interface, which weaken the strength of the binding of the polyelectrolytes to the interface. However, it was shown that the same side chains effectively protect the adsorbed layer against desorption when the layer is exposed to solutions containing an oppositely charged surfactant. Investigation of the lubrication properties of the bottle-brush polyelectrolytes in an asymmetric (mica-silica) system also related the observed favourable frictional properties to the protective nature of the side chains. The decisive factor for achieving very low coefficients of friction was found to be the concentration of the side chains in the gap between the surfaces. Interestingly, it was shown that a brush-like conformation of the bottle-brush polyelectrolyte at the interface has little effect on achieving favourable lubrication properties. However, a brush-like conformation is vital for the resilience of the adsorbed layer against the competitive adsorption of species with a higher surface affinity. / QC 20100830 Polyelectrolyte Surfactant Bottle-Brush Polyelectrolyte Comb Polyelectrolyte Non-Equilibrium State Polymer Architecture Adsorption Desorption Association Excluded Volume Light Scattering SFA AFM QCM-D Turbidimeter Mica Silica Surface Forces Surface and colloid chemistry Yt- och kolloidkemi
117	Microfluidics in Surface Modified PDMS : Towards Miniaturized Diagnostic Tools Thorslund, Sara January 2006 (has links) There is a strong trend in fabricating miniaturized total analytical systems, µTAS, for various biochemical and cell biology applications. These miniaturized systems could e.g. gain better separation performances, be faster, consume less expensive reagents and be used for studies that are difficult to access in the macro world. Disposable µTAS eliminate the risk of carry-over and can be fabricated to a low cost. This work focused on the development of µTAS modules with the intentional use for miniaturized diagnostics. Modules for blood separation, desalting, enrichment, separation and ESI-MS detection were successfully fabricated. Surface coatings were additionally developed and evaluated for applications in µTAS with complex biological samples. The first heparin coating could be easily immobilized in a one-step-process, whereas the second heparin coating was aimed to form a hydrophilic surface that was able to draw blood or plasma samples into a microfluidic system by capillary forces. The last mentioned heparin surface was further utilized when developing a chip-based sensor for performing CD4-count in human blood, an important marker to determine the stage of an HIV-infection. All devices in this work were fabricated in PDMS, an elastomeric polymer with the advantage of rapid and less expensive prototyping of the microfabricated master. It was shown that PDMS could be considered as the material of choice for future commercial µTAS. The devices were intentionally produced using a low grade of fabrication complexity. It was however demonstrated that even with low complexity, it is possible to integrate several functional chip modules into a single microfluidic device. Materials science µTAS micro total analysis system PDMS poly(dimethylsiloxane) microfluidics heparin blood filtration on-chip ESI-MS desalting QCM-D biocompatible CD4 capillary flow lab-on-chip microfabrication enrichment point-of-care hydrophilic oxidation Materialvetenskap
118	On the Development of Mucin-based Biomaterial Coatings Sandberg, Tomas January 2008 (has links) Owing to their key role in mucosal functioning as surface barriers with biospecific interaction potentials, the mucins are interesting candidates for use as surface modifiers in biomaterials applications. In this work, “mild” fractionation procedures were used to prepare mucins of bovine (BSM), porcine (PGM), and human (MG1) origin. Biophysicochemical analysis showed the prepared mucins to differ in size, charge, conformation, and composition. In turn, these factors were shown to govern mucin adsorption on hydrophilic and hydrophobic model surfaces. To enable for detailed coating analysis, methods for the qualitative and quantitative analysis of mucin-based coatings were developed. Of particular interest, a method for the determination of the fraction of surface-exposed, presumed bioactive proteins in a complex mucin coating was described. It was shown, using microscopy and activation assays, that mucin precoating effectively suppresses the neutrophil response towards a polymeric model biomaterial. Under optimal coating conditions, all mucins performed equally well, thus indicating them to be functionally similar. Coating analysis suggested that efficient mucin surface-shielding is critical for good mucin coating performance. Following a study on the complexation of albumin with preadsorbed mucin, we investigated the effect of mucin precoating on the conformation and neutrophil-activating properties of adsorbed host proteins. We found that mucin precoating greatly reduces the strong immune-response normally caused by adsorbed proinflammatory proteins (IgG and sIgA). Detailed coating analysis revealed that the fraction of surface-exposed protein in the mucin-protein composite influences the neutrophil response. Unexpectedly low neutrophil activation for composites containing near-monolayer concentrations of exposed IgG, suggested IgG to act synergistically with mucin on the surface. Conformational analysis supported this by showing that a preadsorbed mucin layer could stabilize adsorbed IgG through complexation. Our findings link well to the complex in vivo situation and suggest that functional mucosal mimics can be created in situ for improved biomaterials performance. Mucin Biomaterial Surface-exposed protein XPS Neutrophil Cell morphology SEM QCM-D Viscoelasticity Protein-stabilization HNL Coating MG1 BSM PGM SEC-MALS-RI Mucin quantification Protein adsorption Ellipsometry Biomaterials Biomaterial
119	A novel biotinylated surface designed for QCM-D applications Nilebäck, Erik January 2009 (has links) Control of protein immobilization at sensor surfaces is of great interest within various scientific fields, since it enables studies of specific biomolecular interactions. To achieve this, one must be able to immobilize proteins with retained native structure, while minimizing non-specific protein binding. The high affinity interaction between streptavidin (SA) and biotin is extensively used as a linker between a surface, where SA is immobilized, and the (biotinylated) molecule of interest. Self- assembled monolayers (SAMs) of poly- and oligo ethylene glycol (PEG and OEG) derivatives have been proven in literature to minimize non-specific protein binding, and biotin-exposing SAMs have been shown efficient for immobilization of SA. The aim of this master's thesis project was to develop biotinylated gold surfaces for quartz crystal microbalance with dissipation monitoring (QCM-D) applications through the self-assembly of mixed monolayers of thiolated OEG (or PEG) derivatives with or without a terminal biotin head group. For this, different thiol compounds were to be compared and evaluated. For the systems under study, the required biotin density for maximum specific SA immobilization was to be established, while keeping the non-specific serum adsorption at a minimum. Model experiments with biotinylated proteins immobilized to the SA-functionalized surfaces were to be performed to evaluate the possibilities for commercialization. A protocol for the preparation of a novel biotinylated surface was developed based on the immersion of gold substrates in an ethanolic incubation solution of dithiols with OEG chains (SS-OEG and SS-OEG-biotin, 99:1) and found to give reproducible results with respect to low non-specific protein binding and immobilization of a monolayer of SA. The modified surfaces allowed for subsequent immobilization of biotinylated bovine serum albumin (bBSA) and biotinylated plasminogen (bPLG). PLG was the subject of a challenging case study, using a combination of QCM-D and surface plasmon resonance (SPR), where the immobilized protein was subjected to low molecular weight ligands that were believed to induce conformational changes. The high control of the surface chemistry allowed for the interpretation of the increased dissipation shift upon ligand binding in terms of conformational changes. An obstacle before commercialization of the described biotinylated surfaces is that they do not seem stable for storage > 7 days. The reasons for this have to be investigated further. QCM-D Self-assembled monolayer SAM thiol ethylene glycol OEG PEG biosensor surface chemistry biotin streptavidin ellipsometry contact angle goniometry surface plasmon resonance SPR impedance spectroscopy IS sensor surface Molecular physics Molekylfysik
120	Nanocomposite films for corrosion protection Sababi, Majid January 2013 (has links) This thesis describes technical and scientific aspects of new types of composite films/coatings for corrosion protection of carbon steel, composite films with nanometer thickness consisting of mussel adhesive protein (Mefp‐1) and ceria nanoparticles, and polymeric composite coatings with micrometre thickness consisting of conducting polymer and ceria nanoparticles in a UV‐curing polyester acrylate (PEA) resin. The influence of microstructure on corrosion behaviour was studied for a Fe‐Cr‐V‐N alloy containing micro‐sized nitrides with different chemical composition spread in martensitic alloy matrix. The Volta potential mapping suggested higher relative nobility for the nitride particles than the alloy matrix, and the nitrides with higher amounts of nitrogen and vanadium exhibited higher nobility. Potentiodynamic polarization measurements in a 0.1 M NaCl solution at neutral pH and ambient temperature showed passivity breakdown with initiation of localized corrosion which started in the boundary region surrounding the nitride particles, especially the ones enriched in Cr and Mo. Mefp‐1/ceria nanocomposite films were formed on silica and metal substrates by layer‐by‐layer immersion deposition. The film formation process was studied in situ using a Quartz Crystal Microbalance with Dissipation (QCM‐D). The film grows linearly with increasing number of immersions. Increasing Mefp‐1 concentration or using Mefp‐1 with larger size leads to more Mefp‐1 being deposited. Peak Force Quantitative Nanomechanical Mapping (Peak Force QNM) of the composite films in air indicated that the elastic modulus of the film increased when the film deposited had a higher Mefp‐1 concentration. It was also noted that the nature of the outermost layer can affect bulk morphology and surface mechanical properties of the film. The QCM‐D study of Mefp‐1 on an iron substrate showed that Mefp‐1 adsorbs at a high rate and changes its conformation with increasing adsorption time. The QCM‐D and in situ Peak Force QNM measurements showed that the addition of Fe3+ ions causes a transition in the single Mefp‐1 layer from an extended and soft layer to a denser and stiffer layer. In situ ATR‐FTIR and Confocal Raman Microscopy (CRM) analyses revealed complex formation between Fe3+ and catechol groups in Mefp‐1. Moreover, optical microscopy, SEM and AFM characterization of the Mefp‐1/ceria composite film formed on carbon steel showed micron‐size aggregates rich in Mefp‐1 and ceria, and a nanostructure of well dispersed ceria particles in the film. The CRM analysis confirmed the presence of Mefp‐1/Fe complexes in the film. Electrochemical impedance microscopy and potentiodynamic polarization measurements showed that the Mefp‐1/ceria composite film can provide corrosion protection for carbon steel, and that the protection efficiency increases with exposure time. Composite coatings of 10 μm thickness composed of a UV‐curing PEA resin and a small amount of conductive polymer and ceria nanoparticles were coated on carbon steel. The conductive polymer (PAni) was synthesized with phosphoric acid (PA) as the dopant by chemical oxidative polymerization. The ATR‐FTIR and SEM analyses confirmed that the added particles were well dispersed in the coatings. Electrochemical measurements during long exposure in 0.1 M NaCl solution, including open circuit potential (OCP) and EIS, were performed to investigate the protective performance of the coatings. The results showed that adding ceria nanoparticles can improve the barrier properties of the coating, and adding PAni‐PA can lead to active protection of the coating. Adding PAni‐PA and ceria nanoparticles simultaneously in the coating can improve the protection and stability of the composite coating, providing excellent corrosion protection for carbon steel. / <p>QC 20131024</p> corrosion protection nanocomposite coating tool alloy layer‐by‐layer polarization passivity nanomechanical topography Mefp‐ 1 ceria nanoparticle PAni UV‐cure AFM Peak Force QNM EIS SEM CRM QCM‐D ATR‐FTIR

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