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Lanthanide-encoded Polysterene Microspheres for Mass Cytometry-based BioassaysAbdelrahman, Ahmed I. 05 January 2012 (has links)
This thesis describes the synthesis and characterization of metal-encoded polystyrene microspheres with a narrow size distribution designed for mass cytometry-based immuno- and oligonucleotide-assays. These particles were prepared by multiple stage dispersion polymerization techniques using polyvinylpyrrolidone (PVP) as a steric stabilizer.
As a cytometeric technique, mass cytometry necessitated metal-encoded microspheres to perform the same roles of fluorescent microspheres used in conventional flow cytometry. The first role of the microsphere was to be able to act as a platform (classifier microspheres) for bioassays. Secondly, the microspheres should be suitable for mass cytometry machine calibration as standards. To perform these roles, metal-encoded microspheres were required to have certain size, functionality and metal content criteria. Lanthanide elements were chosen as the metals for encoding the microspheres for their low natural abundance in biological systems and for their similar chemistry.
My goal was to employ two-stage dispersion polymerization, of styrene in ethanol, to introduce the lanthanide salts along with excess acrylic acid in the second stage, one hour after the initiation. Acrylic acid deemed to serve as a ligand for the lanthanide ions, through its carbonyl group, so the lanthanide ions get incorporated into the microsphere while acrylic acid is copolymerizing with styrene. Using two-stage dispersion polymerization, I could synthesize lanthanide encoded microspheres with narrow size distribution and high lanthanide content. However the lanthanide content distributions were unexpectedly much broader than the size distribution obtained. In addition, I could not attach biomolecules to the surface of such particles.
In an attempt to improve the characteristics of these microspheres, I employed modified versions of multiple stage dispersion polymerization and seeded emulsion polymerization to grow functional polymer shell on the surface of the particles prepared by dispersion polymerization. Moreover, I coated the lanthanide encoded microspheres with silica shell which enabled me to grow another layer of functional-silica. Consequently, I could use these particles as classifier microspheres for mass cytometry-based immunoassays as well as fluorescence-based oligonucleotide-assays.
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Lanthanide-encoded Polysterene Microspheres for Mass Cytometry-based BioassaysAbdelrahman, Ahmed I. 05 January 2012 (has links)
This thesis describes the synthesis and characterization of metal-encoded polystyrene microspheres with a narrow size distribution designed for mass cytometry-based immuno- and oligonucleotide-assays. These particles were prepared by multiple stage dispersion polymerization techniques using polyvinylpyrrolidone (PVP) as a steric stabilizer.
As a cytometeric technique, mass cytometry necessitated metal-encoded microspheres to perform the same roles of fluorescent microspheres used in conventional flow cytometry. The first role of the microsphere was to be able to act as a platform (classifier microspheres) for bioassays. Secondly, the microspheres should be suitable for mass cytometry machine calibration as standards. To perform these roles, metal-encoded microspheres were required to have certain size, functionality and metal content criteria. Lanthanide elements were chosen as the metals for encoding the microspheres for their low natural abundance in biological systems and for their similar chemistry.
My goal was to employ two-stage dispersion polymerization, of styrene in ethanol, to introduce the lanthanide salts along with excess acrylic acid in the second stage, one hour after the initiation. Acrylic acid deemed to serve as a ligand for the lanthanide ions, through its carbonyl group, so the lanthanide ions get incorporated into the microsphere while acrylic acid is copolymerizing with styrene. Using two-stage dispersion polymerization, I could synthesize lanthanide encoded microspheres with narrow size distribution and high lanthanide content. However the lanthanide content distributions were unexpectedly much broader than the size distribution obtained. In addition, I could not attach biomolecules to the surface of such particles.
In an attempt to improve the characteristics of these microspheres, I employed modified versions of multiple stage dispersion polymerization and seeded emulsion polymerization to grow functional polymer shell on the surface of the particles prepared by dispersion polymerization. Moreover, I coated the lanthanide encoded microspheres with silica shell which enabled me to grow another layer of functional-silica. Consequently, I could use these particles as classifier microspheres for mass cytometry-based immunoassays as well as fluorescence-based oligonucleotide-assays.
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Formation et propriétés des cristaux colloïdaux issus de l’auto-assemblage de microsphères de polymèreBazin, Gwénaëlle 04 1900 (has links)
Le besoin pour des biocapteurs à haute sensibilité mais simples à préparer et à utiliser est en constante augmentation, notamment dans le domaine biomédical. Les cristaux colloïdaux formés par des microsphères de polymère ont déjà prouvé leur fort potentiel en tant que biocapteurs grâce à l’association des propriétés des polymères et à la diffraction de la lumière visible de la structure périodique. Toutefois, une meilleure compréhension du comportement de ces structures est primordiale avant de pouvoir développer des capteurs efficaces et polyvalents. Ce travail propose d’étudier la formation et les propriétés des cristaux colloïdaux résultant de l’auto-assemblage de microsphères de polymère en milieu aqueux. Dans ce but, des particules avec différentes caractéristiques ont été synthétisées et caractérisées afin de corréler les propriétés des particules et le comportement de la structure cristalline.
Dans un premier temps, des microsphères réticulées de polystyrène anioniques et cationiques ont été préparées par polymérisation en émulsion sans tensioactif. En variant la quantité de comonomère chargé, le chlorure de vinylbenzyltriméthylammonium ou le sulfonate styrène de sodium, des particules de différentes tailles, formes, polydispersités et charges surfaciques ont été obtenues. En effet, une augmentation de la quantité du comonomère ionique permet de stabiliser de façon électrostatique une plus grande surface et de diminuer ainsi la taille des particules. Cependant, au-dessus d’une certaine concentration, la polymérisation du comonomère en solution devient non négligeable, provoquant un élargissement de la distribution de taille. Quand la polydispersité est faible, ces microsphères chargées, même celles non parfaitement sphériques, peuvent s’auto-assembler et former des cristaux colloïdaux diffractant la lumière visible. Il semble que les répulsions électrostatiques créées par les charges surfaciques favorisent la formation de la structure périodique sur un grand domaine de concentrations et améliorent leur stabilité en présence de sel.
Dans un deuxième temps, le besoin d’un constituant stimulable nous a orientés vers les structures cœur-écorce. Ces microsphères, synthétisées en deux étapes par polymérisation en émulsion sans tensioactif, sont formées d’un cœur de polystyrène et d’une écorce d’hydrogel. Différents hydrogels ont été utilisés afin d’obtenir des propriétés différentes : le poly(acide acrylique) pour sa sensibilité au pH, le poly(N-isopropylacrylamide) pour sa thermosensibilité, et, enfin, le copolymère poly(N-isopropylacrylamide-co-acide acrylique) donnant une double sensibilité. Ces microsphères forment des cristaux colloïdaux diffractant la lumière visible à partir d’une certaine concentration critique et pour un large domaine de concentrations. D’après les changements observés dans les spectres de diffraction, les stimuli ont un impact sur la structure cristalline mais l’amplitude de cet effet varie avec la concentration. Ce comportement semble être le résultat des changements induits par la transition de phase volumique sur les interactions entre particules plutôt qu’une conséquence du changement de taille. Les interactions attractives de van der Waals et les répulsions stériques sont clairement affectées par la transition de phase volumique de l’écorce de poly(N-isopropylacrylamide). Dans le cas des microsphères sensibles au pH, les interactions électrostatiques sont aussi à considérer. L’effet de la concentration peut alors être mis en relation avec la portée de ces interactions.
Finalement, dans l’objectif futur de développer des biocapteurs de glucose, les microsphères cœur-écorce ont été fonctionnalisées avec l’acide 3-aminophénylboronique afin de les rendre sensibles au glucose. Les effets de la fonctionnalisation et de la complexation avec le glucose sur les particules et leur empilement périodique ont été examinés. La structure cristalline est visiblement affectée par la présence de glucose, même si le mécanisme impliqué reste à élucider. / The need for biosensors with high sensibility but simple preparation and use has been increasing, especially in the biomedical field. Crystalline colloidal arrays (CCAs) formed by polymer microspheres have already demonstrated great potential for biosensing applications, combining the polymer properties to the visible light diffraction caused by their periodic structure. However, a better understanding of the behavior of such structures is essential in the objective to develop efficient and versatile biosensors. This work proposes to investigate the formation and properties of CCAs created by the self-assembly of polymer microspheres in aqueous medium. For that purpose, particles with different features have been synthesized and studied to highlight the correlation between the properties of the particles and the behavior of the CCAs.
First, anionic and cationic cross-linked polystyrene microspheres have been prepared by surfactant-free emulsion polymerization. Different sizes, shapes, polydispersities and surface charge densities have been obtained by the use of various amounts of charged comonomers, either vinylbenzyltrimethylammonium chloride or sodium styrenesulfonate. Indeed, an increasing amount of the ionic comonomer leads to a decreasing particle size because of the ability to electrostatically stabilize more surfaces. However, above a certain concentration, the polymerization of the comonomer in solution increases the polydispersity of the particle size. When allowed by a low polydispersity, the charged microspheres can self-assemble into CCAs with intense visible light diffraction, even for particles not quite spherical. It appears that the electrostatic repulsions created by the charges help in the formation of the periodic structure over a wide range of particle concentrations and improve their stability towards ionic strength.
Secondly, the need for a sensitive component brought us to investigate core-shell structures. These microspheres, synthesized by a two-step surfactant-free emulsion polymerization, are made of a polystyrene core and a hydrogel shell. Different hydrogels have been used to achieve different properties: poly(acrylic acid) for pH-sensitivity, poly(N-isopropylacrylamide) for thermosensitivity and poly(N-isopropylacrylamide-co-acrylic acid) for double sensitivity to both stimuli. Above a certain critical concentration, and over a wide range of concentrations, these microspheres also form CCAs with visible light diffraction. The resulting crystalline structures also display a response to the stimuli, visible through changes in the diffraction spectra, but the response appears to be dependent on the microsphere concentration. This behavior seems to be the result of a change in the interactions between particles rather than the outcome of the volume change of the particles. Attractive van der Waals and repulsive steric interactions are clearly affected by the temperature-induced volume phase transition of poly(N-isopropylacrylamide) microspheres. In the case of pH-sensitive, electrostatic interactions are also to be considered. The effect of concentration can then related to the range of the interactions.
Finally, in the objective to develop glucose sensors, the previous microspheres have been functionalized with 3-aminophenylboronic acid to make them responsive to glucose. The effects of the functionalization and complexation with glucose on the particles and their CCAs have been investigated. The crystalline structure is clearly affected by the presence of glucose, even though the mechanism involved remains to be clarified.
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Formation et propriétés des cristaux colloïdaux issus de l’auto-assemblage de microsphères de polymèreBazin, Gwénaëlle 04 1900 (has links)
Le besoin pour des biocapteurs à haute sensibilité mais simples à préparer et à utiliser est en constante augmentation, notamment dans le domaine biomédical. Les cristaux colloïdaux formés par des microsphères de polymère ont déjà prouvé leur fort potentiel en tant que biocapteurs grâce à l’association des propriétés des polymères et à la diffraction de la lumière visible de la structure périodique. Toutefois, une meilleure compréhension du comportement de ces structures est primordiale avant de pouvoir développer des capteurs efficaces et polyvalents. Ce travail propose d’étudier la formation et les propriétés des cristaux colloïdaux résultant de l’auto-assemblage de microsphères de polymère en milieu aqueux. Dans ce but, des particules avec différentes caractéristiques ont été synthétisées et caractérisées afin de corréler les propriétés des particules et le comportement de la structure cristalline.
Dans un premier temps, des microsphères réticulées de polystyrène anioniques et cationiques ont été préparées par polymérisation en émulsion sans tensioactif. En variant la quantité de comonomère chargé, le chlorure de vinylbenzyltriméthylammonium ou le sulfonate styrène de sodium, des particules de différentes tailles, formes, polydispersités et charges surfaciques ont été obtenues. En effet, une augmentation de la quantité du comonomère ionique permet de stabiliser de façon électrostatique une plus grande surface et de diminuer ainsi la taille des particules. Cependant, au-dessus d’une certaine concentration, la polymérisation du comonomère en solution devient non négligeable, provoquant un élargissement de la distribution de taille. Quand la polydispersité est faible, ces microsphères chargées, même celles non parfaitement sphériques, peuvent s’auto-assembler et former des cristaux colloïdaux diffractant la lumière visible. Il semble que les répulsions électrostatiques créées par les charges surfaciques favorisent la formation de la structure périodique sur un grand domaine de concentrations et améliorent leur stabilité en présence de sel.
Dans un deuxième temps, le besoin d’un constituant stimulable nous a orientés vers les structures cœur-écorce. Ces microsphères, synthétisées en deux étapes par polymérisation en émulsion sans tensioactif, sont formées d’un cœur de polystyrène et d’une écorce d’hydrogel. Différents hydrogels ont été utilisés afin d’obtenir des propriétés différentes : le poly(acide acrylique) pour sa sensibilité au pH, le poly(N-isopropylacrylamide) pour sa thermosensibilité, et, enfin, le copolymère poly(N-isopropylacrylamide-co-acide acrylique) donnant une double sensibilité. Ces microsphères forment des cristaux colloïdaux diffractant la lumière visible à partir d’une certaine concentration critique et pour un large domaine de concentrations. D’après les changements observés dans les spectres de diffraction, les stimuli ont un impact sur la structure cristalline mais l’amplitude de cet effet varie avec la concentration. Ce comportement semble être le résultat des changements induits par la transition de phase volumique sur les interactions entre particules plutôt qu’une conséquence du changement de taille. Les interactions attractives de van der Waals et les répulsions stériques sont clairement affectées par la transition de phase volumique de l’écorce de poly(N-isopropylacrylamide). Dans le cas des microsphères sensibles au pH, les interactions électrostatiques sont aussi à considérer. L’effet de la concentration peut alors être mis en relation avec la portée de ces interactions.
Finalement, dans l’objectif futur de développer des biocapteurs de glucose, les microsphères cœur-écorce ont été fonctionnalisées avec l’acide 3-aminophénylboronique afin de les rendre sensibles au glucose. Les effets de la fonctionnalisation et de la complexation avec le glucose sur les particules et leur empilement périodique ont été examinés. La structure cristalline est visiblement affectée par la présence de glucose, même si le mécanisme impliqué reste à élucider. / The need for biosensors with high sensibility but simple preparation and use has been increasing, especially in the biomedical field. Crystalline colloidal arrays (CCAs) formed by polymer microspheres have already demonstrated great potential for biosensing applications, combining the polymer properties to the visible light diffraction caused by their periodic structure. However, a better understanding of the behavior of such structures is essential in the objective to develop efficient and versatile biosensors. This work proposes to investigate the formation and properties of CCAs created by the self-assembly of polymer microspheres in aqueous medium. For that purpose, particles with different features have been synthesized and studied to highlight the correlation between the properties of the particles and the behavior of the CCAs.
First, anionic and cationic cross-linked polystyrene microspheres have been prepared by surfactant-free emulsion polymerization. Different sizes, shapes, polydispersities and surface charge densities have been obtained by the use of various amounts of charged comonomers, either vinylbenzyltrimethylammonium chloride or sodium styrenesulfonate. Indeed, an increasing amount of the ionic comonomer leads to a decreasing particle size because of the ability to electrostatically stabilize more surfaces. However, above a certain concentration, the polymerization of the comonomer in solution increases the polydispersity of the particle size. When allowed by a low polydispersity, the charged microspheres can self-assemble into CCAs with intense visible light diffraction, even for particles not quite spherical. It appears that the electrostatic repulsions created by the charges help in the formation of the periodic structure over a wide range of particle concentrations and improve their stability towards ionic strength.
Secondly, the need for a sensitive component brought us to investigate core-shell structures. These microspheres, synthesized by a two-step surfactant-free emulsion polymerization, are made of a polystyrene core and a hydrogel shell. Different hydrogels have been used to achieve different properties: poly(acrylic acid) for pH-sensitivity, poly(N-isopropylacrylamide) for thermosensitivity and poly(N-isopropylacrylamide-co-acrylic acid) for double sensitivity to both stimuli. Above a certain critical concentration, and over a wide range of concentrations, these microspheres also form CCAs with visible light diffraction. The resulting crystalline structures also display a response to the stimuli, visible through changes in the diffraction spectra, but the response appears to be dependent on the microsphere concentration. This behavior seems to be the result of a change in the interactions between particles rather than the outcome of the volume change of the particles. Attractive van der Waals and repulsive steric interactions are clearly affected by the temperature-induced volume phase transition of poly(N-isopropylacrylamide) microspheres. In the case of pH-sensitive, electrostatic interactions are also to be considered. The effect of concentration can then related to the range of the interactions.
Finally, in the objective to develop glucose sensors, the previous microspheres have been functionalized with 3-aminophenylboronic acid to make them responsive to glucose. The effects of the functionalization and complexation with glucose on the particles and their CCAs have been investigated. The crystalline structure is clearly affected by the presence of glucose, even though the mechanism involved remains to be clarified.
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STUDIUM CHOVÁNÍ CEMENTOVÝCH KOMPOZITŮ PŘI PŮSOBENÍ VYSOKÝCH TEPLOT / BEHAVIOUR OF CEMENTITIOUS COMPOSITES EXPOSED TO HIGH TEMPERATURESNováková, Iveta Unknown Date (has links)
Fire resistance is becoming increasingly important along with the development of new concrete types with high strength and dense structure with reduced porosity. Such concrete types are susceptible to fire spalling and extensive crack formation. At the moment, there are a limited number of methods for enhancement of fire resistance of existing structures, which could be applied in underground structures with restricted space and limited air exchange, such as tunnels, underground garages or nuclear powerplants. This work is focused on the development of two methods, and both are dealing with porous structure modification. The first method is intentional heat treatment (IHT) method, suitable for the enhancement of fire resistance of existing structures. The second method emphasized the design of air-entrained concrete (AeA-FiResCrete) with the use of “new generation” air-entraining agents suitable for enhancement of fire resistance of newly designed concrete. Testing of compressive strength, porous structure modification was completed by the analysis of “moisture clog,” which contributes to explosive spalling and extensive cracking. The efficiency of developing methods was verified during large-scale testing according to modified ISO834 (m-ISO) curve. No extensive crack formation or explosive spalling was observed during the exposure period during the large-scale testing of slabs with the applied IHT method. The total thickness of the IHT method with configuration IHT200/2, composed of IHT zone and IHT transition zone, penetrated to the depth of 25,5 to 43,0 mm depending upon various concrete types. Moisture clog in AeA-FiResCrete was more significant than in the case of slabs with applied IHT method, and it could be concluded that the IHT method enhances fire resistance of concrete exposed to elevated temperatures without influencing its compressive strength and durability. Results from AeA-FiResCrete testing showed only a slight improvement of its fire resistance.
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