Global ETD Search

141	HILIC-MS analysis of protein glycosylation using nonporous silica Rachel E. Jacobson (5929808) 16 January 2019 (has links) The objective of this research is to develop and apply a HILIC UHPLC stationary phase that allows for separation of intact glycoproteins. In Chapter 1 I give an overview of the problems of current glycosylation profiling with regards to biotherapeutics, and my strategy to separate the intact glycoprotein with HILIC. Chapter 2 describes the methods used to produce the nonporous packing material and stationary phase. In Chapter 3 I describe previous work in developing a HILIC polyacrylamide stationary phase, and further improvements I have made. Chapter 4 describes development of an assay in collaboration with Genentech of therapeutic mAb glycosylation. In Chapter 5, I show HILIC-MS of digested ribonuclease B as a beginning step to analyze glycosylated biomarkers. Separation Science Proteins and Peptides Colloid and Surface Chemistry hplc lcms uplc uhplc liquid chromatography HILIC biologics mAbs antibodies protein glycan glycosylation glycoform MS mass spectrometry AGET ATRP surface-initiated
142	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
143	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
144	Polysaccharide-based Polyion Complex Micelles as New Delivery Systems for Hydrophilic Cationic Drugs Soliman, Ghareb Mohamed 08 1900 (has links) Les micelles polyioniques ont émergé comme des systèmes prometteurs de relargage de médicaments hydrophiles ioniques. Le but de cette étude était le développement des micelles polyioniques à base de dextrane pour la relargage de médicaments hydrophiles cationiques utilisant une nouvelle famille de copolymères bloc carboxymethyldextran-poly(éthylène glycol) (CMD-PEG). Quatre copolymères CMD-PEG ont été préparés dont deux copolymères identiques en termes de longueurs des blocs de CMD et de PEG mais différent en termes de densité de charges du bloc CMD; et deux autres copolymères dans lesquels les blocs chargés sont les mêmes mais dont les blocs de PEG sont différents. Les propriétés d’encapsulation des micelles CMD-PEG ont été évaluées avec différentes molécules cationiques: le diminazène (DIM), un médicament cationique modèle, le chlorhydrate de minocycline (MH), un analogue semi-synthétique de la tétracycline avec des propriétés neuro-protectives prometteuses et différents antibiotiques aminoglycosidiques. La cytotoxicité des copolymères CMD-PEG a été évaluée sur différentes lignées cellulaires en utilisant le test MTT et le test du Bleu Alamar. La formation de micelles des copolymères de CMD-PEG a été caractérisée par différentes techniques telles que la spectroscopie RMN 1H, la diffusion de la lumière dynamique (DLS) et la titration calorimétrique isotherme (ITC). Le taux de relargage des médicaments et l’activité pharmacologique des micelles contenant des médicaments ont aussi été évalués. Les copolymères CMD-PEG n'ont induit aucune cytotoxicité dans les hépatocytes humains et dans les cellules microgliales murines (N9) après 24 h incubation pour des concentrations allant jusqu’à 15 mg/mL. Les interactions électrostatiques entre les copolymères de CMD-PEG et les différentes drogues cationiques ont amorcé la formation de micelles polyioniques avec un coeur composé du complexe CMD-médicaments cationiques et une couronne composée de PEG. Les propriétés des micelles DIM/CMDPEG ont été fortement dépendantes du degré de carboxyméthylation du bloc CMD. Les micelles de CMD-PEG de degré de carboxyméthylation du bloc CMD ≥ 60 %, ont incorporé jusqu'à 64 % en poids de DIM et ont résisté à la désintégration induite par les sels et ceci jusqu'à 400 mM NaCl. Par contre, les micelles de CMD-PEG de degré de carboxyméthylation ~ 30% avaient une plus faible teneur en médicament (~ 40 % en poids de DIM) et se désagrégeaient à des concentrations en sel inférieures (∼ 100 mM NaCl). Le copolymère de CMD-PEG qui a montré les propriétés micellaires les plus satisfaisantes a été sélectionné comme système de livraison potentiel de chlorhydrate de minocycline (MH) et d’antibiotiques aminoglycosidiques. Les micelles CMD-PEG encapsulantes de MH ou d’aminoglycosides ont une petite taille (< 200 nm de diamètre), une forte capacité de chargement (≥ 50% en poids de médicaments) et une plus longue période de relargage de médicament. Ces micelles furent stables en solution aqueuse pendant un mois; après lyophilisation et en présence d'albumine sérique bovine. De plus, les micelles ont protégé MH contre sa dégradation en solutions aqueuses. Les micelles encapsulant les drogues ont maintenu les activités pharmacologiques de ces dernières. En outre, les micelles MH réduisent l’inflammation induite par les lipopolysaccharides dans les cellules microgliales murines (N9). Les micelles aminoglycosides ont été quant à elles capable de tuer une culture bactérienne test. Toutefois les micelles aminoglycosides/CMDPEG furent instables dans les conditions physiologiques. Les propriétés des micelles ont été considérablement améliorées par des modifications hydrophobiques de CMD-PEG. Ainsi, les micelles aminoglycosides/dodecyl-CMD-PEG ont montré une taille plus petite et une meilleure stabilité aux conditions physiologiques. Les résultats obtenus dans le cadre de cette étude montrent que CMD-PEG copolymères sont des systèmes prometteurs de relargage de médicaments cationiques. / Polyion complex (PIC) micelles have emerged as promising delivery systems of ionic hydrophilic drugs. It was the aim of this study to develop dextran-based PIC micelles for the delivery of hydrophilic cationic drugs using a new family of carboxymethyldextranblock- poly(ethylene glycol) (CMD-PEG) copolymers. Four CMD-PEG copolymers were prepared: (i) two copolymers identical in terms of the length of CMD and PEG blocks, but different in terms of the charge density of the CMD block; and (ii) two copolymers in which the charged block is the same, but the PEG block is of different molecular weight. The micellization of CMD-PEG copolymers and drug delivery aspects of the resulting micelles were evaluated using different cationic drugs: diminazene (DIM), a model cationic drug, minocycline hydrochloride (MH), a semisynthetic tetracycline antibiotic with promising neuroprotective properties and different aminoglycoside antibiotics. The cytotoxicity of CMD-PEG copolymers was evaluated in different cell lines using MTT and Alamar blue assays. CMD-PEG micelles encapsulating different drugs were characterized using different techniques, such as 1H NMR spectroscopy, dynamic light scattering (DLS), and isothermal titration calorimetry (ITC). The pattern of drug release and pharmacological activity of micelles-encapsulated drugs were also evaluated. The CMD-PEG copolymers did not induce cytotoxicity in human hepatocytes and murine microglia (N9) in concentrations as high as 15 mg/mL after incubation for 24 h. Electrostatic interactions between CMD-PEG copolymers and different cationic drugs triggered the formation of PIC micelles with a CMD/drug core and a PEG corona. The properties of DIM/CMD-PEG micelles were strongly dependent on the degree of carboxymethylation of the CMD block. Micelles of CMD-PEG copolymers having degree of carboxymethylation ≥ 60%, incorporated up to 64 wt% DIM, resisted salt-induced disintegration in solutions up to 400 mM NaCl and sustained DIM release under physiological conditions (pH 7.4, 150 mM NaCl). In contrast, micelles of CMD-PEG of degree of carboxymethylation ~ 30% had lower drug content (~ 40 wt% DIM) and disintegrated at lower salt concentration (∼ 100 mM NaCl). The CMD-PEG copolymer that showed the most satisfactory micellar properties, in terms of high drug loading capacity, sustained drug release and micelles stability was selected as a potential delivery system of minocycline hydrochloride (MH) and different aminoglycosides. CMD-PEG micelles encapsulating either MH or aminoglycosides had small size (< 200 nm in diameter), high drug loading capacity (≥ 50 wt% drug) and sustained drug release. These micelles were stable in aqueous solution for up to one month, after freeze drying and in the presence of bovine serum albumin. Furthermore, the micelles protected MH against degradation in aqueous solutions. Micelles-encapsulated drugs maintained their pharmacological activity where MH micelles reduced lipopolysaccharides-induced inflammation in murine microglia (N9) cells. And aminoglycosides micelles were able to kill a test micro-organism (E. coli X-1 blue strain) in culture. Aminoglycosides/CMD-PEG micelles were unstable under physiological conditions. Micelle properties were greatly enhanced by hydrophobic modification of CMD-PEG. Thus, aminoglycosides/dodecyl-CMD-PEG micelles showed smaller size and better stability under physiological conditions. The results obtained in this study show that CMD-PEG copolymers are promising delivery systems for cationic hydrophilic drugs. Dextrane Micelles polyioniques Diminazène Médicaments hydrophiles Minocycline Neuro-inflammation Aminoglycosides Stabilité des micelles Dextran Hydrophilic drugs Polyion complex micelles Diminazene Minocycline Micelles stability Aminoglycosides Neuroinflammation
145	Experimental and Theoretical Studies of Liquid Drop Impact on Solid Surfaces Comprising Smooth and Texture Portions Vaikuntanathan, Visakh January 2015 (has links) (PDF) Solid surfaces featuring a spatial variation of surface wettability along particular directions on their surface, referred to as wettability gradient surfaces, are becoming increasingly important in practical applications such as enhancement of boiling and condensation heat transfer and separation of immiscible liquids in smart micro-fluidic devices. With the aid of an external energy input, such as mechanical vibration or impact kinetic energy, a liquid drop on such surfaces gets propelled towards more wettable region on the surface. A fundamental study of impact dynamics of liquid drops on such solid surfaces is relevant in understanding their effectiveness. The present thesis reports a combined experimental and theoretical study on the impact dynamics of liquid drops on solid surfaces comprising a smooth portion and a groove-textured portion separated by a junction line (dual-textured surfaces). Three different dual-textured surfaces – two made of intrinsically hydrophilic stainless steel and one of intrinsically hydrophobic poly-di-methyl-siloxane (PDMS) – are considered. Liquid drops, with Weber number (We) in the range 1–100, are impacted on the junction of the dual-textured surfaces and the entire impact dynamics across the junction is captured using a high speed video camera. Experiments of drop impact on the homogeneous surface portions of dual-textured surfaces (far away from the junction) are also conducted. The temporal variation of drop contact radius measured from the junction line on smooth and groove-textured portions of the dual-textured surfaces exhibits four distinct stages – primary spreading, primary receding, secondary spreading on more wettable surface portion, and final equilibrium – with the final outcome being the bulk movement and deposition of liquid drop away from the junction towards the more hydrophilic surface portion. Secondary parameters characterizing each of these different stages are extracted from these measurements and a one-to-one comparison between dual-textured and homogenous surfaces is presented. A significant effect of dual-texture nature is seen on the receding process of impacting drops. On the dual-textured surfaces, the receding velocity of impacting drop on the groove-textured portion is always greater than that on the smooth portion. The asymmetry in drop receding results in a drop drift velocity towards the more wettable surface portion leading to an enhanced secondary drop spreading on the more wettable smooth portion. The drop drift velocity shows a decrease with We at low We and remains almost constant at higher We after a particular value of We. Correspondingly, the ratio of the maximum drop spread factor achieved during the secondary spreading (βm2) to that during the primary spreading (βm) is seen to decrease with We at low We and remains constant at higher We. Owing to the differences in the static equilibrium wetting difference, βm2/βm is more on the stainless steel dual-textured surfaces than on the PDMS dual-textured surface. The presence of dual-texture results in a higher final spread on more wettable smooth portion and smaller final spread on less wettable textured portion of the dual-textured surfaces and this difference decreases with We. The difference in final spread factors between the smooth and textured portions is more on the stainless steel dual-textured surfaces than the PDMS dual-textured surface. The bulk drop movement (ξ), characterized in terms of distance measured from the junction to the final drop center, decreases with We at low We and remains constant at higher We on the stainless steel dual-textured surfaces whereas it remains constant at low We and decreases at higher We on the PDMS dual-textured surface. ξ on the PDMS dual-textured surface is always less than that on the stainless dual-textured surface due to the lower wetting difference across the junction of the former. Comparison of the trends of secondary parameters with the predictions from theoretical models reported in literature showed a lack of agreement. This is due to various physical processes encountered by impacting drop on the groove-textured surface, identified through experiments of drop impact on homogeneous groove-textured surfaces, such as (i) convex shape of liquid-vapor interface near contact line at maximum spreading, (ii) impregnation of drop liquid into the grooves during impact, and (iii) contact line pinning of spreading drop at the asperity edges of surface texture, as well as the wetting difference in dual-textured surfaces. The inclusion of these physical processes under conventional energy conservation approach is seen to predict the experimentally observed trends of maximum drop spread factor on the groove-textured portions. A force balance model, applied to the liquid drop configuration at the beginning of drop receding on the dual-textured surfaces, predicts the qualitative trend of ξ with We on all surfaces. Drop liquid impregnation into the grooves of textured portion at We > Wecr (critical We corresponding to transition from Cassie to impaled state) is proposed as a possible physical mechanism to account for the explanation of the specific trends of ξ with We. A theoretical model formulated using force balance at the three phase contact line beneath impacting drop on groove-textured surface is presented for the prediction of Wecr. Combustion Engines Aircraft Structures - Cooling Liquid Drop - Dynamics Dual-textured Surface - Drop Impact Hydrophilic Stainless Steels Hydrophobic Materials - Surface Liquid Drop Impact Groove-textured Surfaces - Drop Impact Groove-textured Solid Surfaces Aerospace Engineering
146	Matériaux hybrides mésoporeux fonctionnalisés par des polymères : élaboration, caractérisation physico-chimique et applications biomédicales / Mesoporous hybrid materials functionalized by polymers : preparation, physicochemical characterization and biomedical applications Molina, Émilie 10 December 2015 (has links) Ce travail de thèse porte sur l’élaboration de matériaux siliciques mésostructurés par des agents structurants originaux : les micelles complexes de polyions ou micelles PICs, qui présentent la particularité de s’assembler de façon réversible dans l’eau. Les micelles PICs sont des assemblages formés par interactions électrostatiques entre un copolymère à blocs double-hydrophiles (DHBC) neutre-ionisable et un agent de micellisation de charge opposée au DHBC. Le DHBC utilisé est un poly(oxyde d’éthylène)-b-poly(acide acrylique) POE-b-PAA synthétisé par polymérisation radicalaire contrôlée par transfert d’atome (ATRP) et les agents de micellisation sont commerciaux (oligochitosane OC, antibiotiques aminoglycosides). Tout d’abord, l’influence de divers paramètres (pH, température, concentration) sur les propriétés d’association des micelles PIC a été étudiée en solution aqueuse. Puis, l’influence de ces mêmes paramètres sur la structuration de la silice en présence de complexes de polyions POE-b-PAA/OC a été recherchée, et a permis de mieux appréhender les mécanismes de formation des matériaux hybrides. Il a ainsi été montré qu’en jouant sur les interactions entre les divers constituants, il était possible de contrôler la mésostructure des matériaux (hexagonale, lamellaire, vermiculaire) et leur morphologie (nanoparticules, microparticules). Enfin, la versatilité de l’utilisation de micelles PIC en tant qu’agents structurants de la silice a été mise en évidence avec des systèmes POE-b-PAA/aminoglycosides, qui ont permis d’obtenir directement des matériaux structurés ordonnés chargés en principes actifs. Par ailleurs, les possibilités offertes par l’utilisation des micelles PIC notamment en termes de fonctionnalité et de réversibilité de la micellisation, ont été exploitées et ont permis d’obtenir facilement des matériaux mésoporeux fonctionnalisés par les chaînes ionisables du DHBC, suite à l’extraction sélective de l’agent de micellisation. Il a été montré que de tels matériaux fonctionnels sont capables de complexer des espèces de charges opposées et notamment des principes actifs, qui peuvent par la suite être relargués de façon pH-dépendante. / Mesostructured hybrid materials were prepared by using original silica-structuring agents, which are polyion complex (PIC) micelles. A great advantage of PIC micelles is that they can be reversibly assembled in aqueous solution by varying physico-chemical parameters. PIC micelles are formed by electrostatic complexation between a neutral-anionic double-hydrophilic block copolymer (DHBC) and an oppositely charged agent of micellization; here a poly(ethylene oxide)-b-poly(acrylic acid) PEO-b-PAA (synthesized by controlled radical polymerization by atom transfer ATRP) and commercial polyamines (oligochitosan OC or aminoglycoside antibiotics) were respectively used. First, the influence of various parameters (pH, temperature, concentration) on PIC micelle association properties was investigated in aqueous solution. Then, the effect of these parameters on the silica mesostructuring process was studied, it provides a better understanding of the formation mechanisms. It was shown that varying interactions between constituents allows to control the mesostructure (hexagonal, lamellar, wormlike) and the material morphology (nanoparticle, microparticle). Finally, the versatility of the approach has been demonstrated with PEO-b-PAA/aminoglycoside systems. Drug-loaded ordered mesostructured materials were prepared following a one-pot route. Moreover, taking advantage of the high degree of functionality of DHBC polymers and of the reversibility of the micellization, polyacid-functionalized mesoporous materials were directly prepared by selectively extracting the micellization agent. PAA-functionalized silica materials were then used to complex diverse active entities such as drugs, whose delivery could be pH-controlled. Chimie sol-Gel Fonctionnalisation Applications biomédicales Polyions Complex Micelles (PIC micelle) Sol-Gel chemistry Mesostructured and Mesoporous Materials Functionalization Biomedical applications 540
147	Le rôle de l’eau dans la structuration des silices mésoporeuses par des complexes électrostatiques / The role of water in the structuring of mesoporous silicas by electrostatic complexes Mathonnat, Mélody 27 November 2017 (has links) Ce travail de thèse porte sur la compréhension des phénomènes physico-chimiques régissant les propriétés poreuses et structurales de matériaux mésoporeux structurés par des micelles complexes de polyions (PIC). Nous défendons que la sensibilité de la structure aux conditions physico-chimiques est due à l’eau contenue dans les complexes électrostatiques en équilibre osmotique avec l’ensemble de la solution.Le travail a consisté à synthétiser par ATRP des copolymères double-hydrophiles (DHBC) POE-b-PAA séquencés neutre-acide faible. En présence d’un polyélectrolyte faible basique, tel que la néomycine ou des oligochitosans, ils forment des micelles PIC, analogues colloïdaux des coacervats. Nous avons caractérisé les micelles PIC de structure cœur-couronne sur une large gamme de concentration et observé leur compression progressive concomitante à leur ordonnancement et finalement leur transition vers des phases lamellaires. La composition du cœur a été étudiée grâce à un système modèle coacervat, macroscopiquement séparé, obtenu par mélange de PAA et de néomycine. Le coacervat contient jusqu’à 60% d’eau et présente la structure d’un réseau de polymères neutres enchevêtrés. La quantité d’eau contenue dans le coacervat dépend des conditions physico-chimiques telles que le pH et la concentration mais également de l’ajout d’osmolytes tels que de l’alcool, du PEG ou du sel. Une série de matériaux mésoporeux a été synthétisée et nous avons montré qu’il était possible de modifier les propriétés structurales et poreuses des matériaux en utilisant un système PIC (couple DHBC + polyélectrolyte) unique, en jouant sur la physico-chimie des solutions de synthèse. Nous avons donc mis en relation les fractions volumiques de cœur complexe du système mésogène et la structure des matériaux obtenus et avons montré que la contribution de l’eau était très significative. L’augmentation de la quantité d’eau dans les coacervats induit une augmentation de la taille des pores ou la transition vers des mésostructures lamellaires de courbures plus faibles. Ainsi la synthèse de matériaux mésoporeux structurés par des complexes électrostatiques s’avère d’autant plus respectueuse de l’environnement qu’elle utilise comme agent structurant principal l’eau. / The objective of this PhD thesis is to understand the physico-chemical phenomena that govern the structural and porous properties of ordered mesoporous materials templated by polyion electrostatic complex micelles. It is defended that the sensitivity of the structure to the physico-chemical parameters of the system is due to the water content in the electrostatic complex which is in osmotic equilibrium with the synthesis medium. First, double-hydrophilic block copolymers (DHBC) were synthesized by ATRP controlled polymerization. They form polyion complex (PIC) micelles in the presence of oppositely charged polyelectrolytes such as the neomycin and oligochitosan weak bases. PIC micelles, colloidal analogues to coacervates, were characterized on a large range of concentration and their concomitant progressive compression was observed together with their ordering and finally their transition to lamellar phases. The core structure and composition were studied through the analysis of a model coacervate system, which macroscopically separates and results from complexation between neomycin and sodium polyacrylate. The coacervate contains up to 60 wt.% of water and exhibits the structure of a network of interpenetrated polymers. The water content in the coacervate depends on physicochemical conditions such as pH and concentration of the system, but also on the addition of osmolytes such as alcohol, PEG polymers or simple salts. A series of mesoporous materials were prepared and their structural and porous properties were modulated by simply varying the physicochemical conditions of the synthesis medium, with a unique DHBC/polyelectrolyte pair. Correlations between the volume fraction of the complex core of the mesogenic system and the obtained material structure could be established and it was shown that the contribution of water was highly significant. Increasing the water content in the coacervates induces an increase of the pore size in 2D hexagonal structures or favours the transition towards lamellar phases of lower curvature. As a conclusion, the synthesis of mesoporous materials mediated by the use of electrostatic complex micelles proved to be all the more environment-friendly as it uses water as the main porogen. Copolymères à blocs double hydrophiles Matériaux mésoporeux Micelles complexes de polyions Pression osmotique Diffusion de rayonnement Comportement lyotrope Ouble-Hydrophilic-Block copolymers Mesoporous materials Polyion Complex Micelles Osmotic pressure Ray-Scattering Lyotropic behavior
148	Obtenção de membranas hidrofílicas a base de PVP (Poli N-vinil-2-pirrolidona) contendo alginato de sódio e nanocarga de pseudoboemita obtida pelo processo sol-gel Barbosa, Isabella Tereza Ferro 03 March 2011 (has links) Made available in DSpace on 2016-03-15T19:36:29Z (GMT). No. of bitstreams: 1 Isabella Tereza Ferro Barbosa.pdf: 1500669 bytes, checksum: 82ebaab9bd4deeb9abb1fde076f7951a (MD5) Previous issue date: 2011-03-03 / Fundo Mackenzie de Pesquisa / The use of hydrogels combined with various additives in tissue regeneration and wound scarring, injuries and burnings has been an option in treatments of difficult scarring, infected-bleeding wounds, burnings and other diseases whose treatments, moist and sterilized resources are required. The hydrogels based on poly (N-vinyl-2-pyrrolidone) are membranes that form an effective barrier over the wound. It protects against the intrusion of external bacteria. It allows the passage in and out of oxygen and medicaments, since they are permeable to them. Pseudobohemite obtained by the sol-gel process are nanoparticles that present a highly superficial area, with expressive characteristic of bleeding absorption. They can adsorb large concentrations of medicaments released gradually in a site containing large amount of water, as it is the case of hydrogel membranes. The therapeutical attributes of hydrogel membranes are highly influenced by the presented concentration of water, about 85 to 90%, which determines the useful life and mechanical attributes of the product. Hydrogel based on PVP presents poor mechanical properties, which makes more difficult the handling of larger curatives. The objective of the study in obtaining hydrogel, based on PVP containing sodium alginate and nanoparticles of pseudobohemite obtained by sol-gel process consists in getting membranes with better mechanical properties and possible to incorporate suitable drugs to each kind of injures. In this study, were obtained and characterized membranes PVP based hydrogels (10%) containing sodium alginate nanoparticles pseudoboehmite concentrations of 1% and 3% respectively. The membranes were obtained by ionizing radiation dose of 25 kGy. The characterization of the membranes was performed by means of tensile tests and the physical-chemical gel fraction / fraction of the sun, swelling, dehydration isotherm is a function of time and thermal analysis. The results showed that the membranes of PVP containing sodium alginate showed higher degree of crosslinking (gel fraction higher), greater strength, greater degree of dehydration as a function of time and gel fraction higher water absorption compared to traditional membranes, only based PVP. / O uso de hidrogéis combinados com diversos aditivos na regeneração de tecidos e cicatrizações em ferimentos, lesões e queimaduras vem sendo uma opção em tratamentos de difícil cicatrização, em ferimentos infeccionados com exsudação e outras enfermidades cujos tratamentos necessitam de meios úmidos e estéreis. Os hidrogéis a base de poli (N-vinil-2- pirrolidona) são membranas que formam uma barreira efetiva no ferimento, contra a intrusão de bactérias externas, embora permitam a passagem de oxigênio e de medicamentos, por serem permeáveis a eles. Pseudoboemitas obtidas pelo processo sol-gel são nanopartículas que apresentam uma alta área superficial, além de apresentar expressivas propriedades de absorção do exsudado, podem adsorver grande concentração de medicamentos e estes são liberados gradativamente em um meio contendo grande quantidade de água como é o caso das membranas de hidrogéis. As propriedades terapêuticas das membranas de hidrogel são altamente influenciadas pela concentração de água presente, que deve ser ao redor de 85 a 90%, a qual determina a vida útil e as propriedades mecânicas do produto. Os hidrogéis produzidos somente a base de PVP apresentam propriedades mecânicas pobres o que dificulta o manuseio de curativos com maiores dimensões. O interesse do estudo da obtenção de hidrogéis a base de PVP contendo alginato de sódio e nanocarga de pseudoboemita obtida pelo processo sol-gel consiste em obter membranas com melhores propriedades mecânicas e com a possibilidade de incorporação de fármacos adequados a cada tipo de lesão. Neste trabalho foram obtidas e caracterizadas membranas de hidrogéis a base de PVP (10%) contendo alginato de sódio e nanocarga de pseudoboemita nas concentrações de 1% e 3%, respectivamente. As membranas foram obtidas por radiação ionizante com dose de 25 kGy. A caracterização das membranas foi realizada por meio de ensaios mecânicos de tração e ensaios físico-químicos de fração gel/fração sol, intumescimento, desidratação isotérmica em função do tempo e análises térmicas. Os resultados mostraram que as membranas de PVP contendo alginato de sódio apresentaram maior grau de reticulação (maior fração gel), maior resistência mecânica, maior grau de desidratação em função do tempo fração gel e maior absorção de água em relação às membranas tradicionais, somente a base de PVP. poli(N-vinil-2-pirrolidona)-PVP membrana hidrofílica pseudoboemita alginato de sódio processo sol-gel poly (N-vinyl-2-Pyrrolidone)-PVP hydrophilic membrane pseudoboehmite sodium alginate sol-gel process
149	Dissolução de comprimidos e péletes de liberação prolongada empregando-se os métodos da pá e Bio-Dis / Dissolution of tablets and pellets of prolonged release using the methods of the blade and Bio-Dis Bianca Ramos Pezzini 13 April 2007 (has links) Matrizes hidrofílicas de diclofenaco sódico e de cetoprofeno foram preparadas por meio de compressão direta ou granulação úmida seguida de compressão, utilizando-se hipromelose para modular a dissolução do fármaco. Foram também obtidos péletes de liberação prolongada de cetoprofeno, mediante extrusão-esferonização e revestimento, em leito fluidizado, com Kollicoat® EMM 30D. Um planejamento fatorial 22 foi usado para elucidar os efeitos de variáveis de formulação sobre os perfis de liberação do fármaco a partir dos sistemas em estudo, determinados empregando-se os métodos da pá e/ou Bio-Dis. No caso dos comprimidos matriciais, os efeitos do grau de viscosidade e concentração de hipromelose foram investigados. Para os péletes, avaliou-se os efeitos da granulometria e ganho de peso em revestimento. A influência do pH sobre a liberação do fármaco a partir dos sistemas preparados foi também estudada, usando-se meios de dissolução com pH 1,2-7,2. Os métodos ANOVA e teste de Tukey (comparação estatística entre porcentuais de fármaco dissolvido e/ou eficiência de dissolução), f1, f2 e Weibull foram usados para caracterizar e comparar os perfis de dissolução. O grau de viscosidade e concentração de hipromelose influenciaram a liberação de diclofenaco sádico e cetoprofeno a partir das matrizes em estudo, sendo a concentração do polímero o fator principal que governou o processo. A granulação alterou os perfis de dissolução de cetoprofeno em relação às matrizes obtidas por compressão direta, diminuindo a velocidade e modificando o mecanismo de liberação. No caso dos péletes, o ganho de peso em revestimento foi o parâmetro que exerceu maior efeito sobre a liberação do cetoprofeno, enquanto a granulometria apenas influenciou os perfis de dissolução dás formulações com maior ganho de peso em revestimento. A liberação do fármaco a partir dos sistemas em estudo aumentou com a elevação do pH, o que ocorreu devido à solubilidade pH-dependente do cetoprofeno e diclofenaco sódico. / Diclofenac sodium and ketoprofen hydrophilic matrices were prepared by direct compression or wet granulation followed by compression, using hypromellose to modulate the drug dissolution. Sustained release ketoprofen pellets were also obtained by extrusion-spheronization and fluidized bed coating with Kollicoat® EMM 30D. A 22 factorial design has been used to elucidate the effects of formulation variables on the drug release profiles from the systems in study, determined using the paddle method and Bio-Dis. In the case of matrix tablets, the effects of the viscosity grade and concentration of hypromellose were investigated. For the pellets, the effects of granulometry and weight gain were evaluated. The influence of the pH value on the drug release from the prepared systems was also studied, using pH 1,2-7,2 dissolution media. ANOVA and Tukey\'s test (statistical comparison between percentages of drug dissolved and/or dissolution efficiency), f1, f2 and Weibull methods were used to characterize and compare the dissolution profiles. The concentration and viscosity grade of hypromellose influenced the ketoprofen and diclofenac sodium release from the studied matrices, being the polymer concentration the main factor that has governed the process. Granulation has modified the dissolution profiles of ketoprofen in relation to the matrices obtained by direct compression, reducing the rate and modifying the mechanism of drug release. In the pellets case, weight gain was the main factor that has influenced the ketoprofen release, while ganulometry has only influenced the dissolution profiles of the formulation with the highest weight gain. Drug release from the systems under study increased with the increase of the pH value of the medium because of the diclofenac sodium and ketoprofen pH-dependent solubility. Bio-Dis Cetoprofeno Comprimidos (Estudo) Diclofenaco sódico Farmacotécnica Hipromelose Kollicoat® EMM 30D Matriz hidrofílica Péletes Tecnologia farmacêutica Bio-Dis Diclofenac sodium Hydrophilic matrix Hypromellose Ketoprofen Kollicoat® EMM 30D Pellets Pharmaceutical technology Pharmacotechnics Pills (Study)
150	Vliv molekulové hmotnosti polypropylénu na izotermickou krystalizaci nanokompozitů / The influence of molecular weight of polypropylene on isothermal crystallization of nanocomposites Krajčik, Ladislav Unknown Date (has links) This work deals with the study of the influence of metallocene type polypropylene (mPP) molecular weight on isothermal crystallization of its nanocomposites filled with hydrophobic and hydrophilic nanosilica (1 and 2 vol.%). Real amount of nanosilica was determined by thermogravimetry. Isothermal crystallization was performed on differential scanning calorimeter (DSC) at 119–125 °C and observed in-situ under optical polarizing microscope (POM) at 128 °C using hot stage. The increase of mPP crystallinity degree in time was determined on DSC and spherulite type and growth rate was determined using POM. Supramolecular surface structure of the original and isothermally crystallited nanocomposites was observed directly or after chemical etching (mixture of mineral acids with KMnO4) on confocal laser scanning microscope. The crystal structure of mPP was in all tested materials verified by X-ray diffraction.

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