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71	Estudo Eletroquímico de Catalisadores de Pt-Mo e Pt-Cd para a Oxidação Eletroquímica de Etileno Glicol para a possível Aplicação em Células a Combustível Diretas a Álcool / Electrochemical Study of Pt-Mo and Pt-Cd Catalysts for Electrochemical Oxidation of Ethylene Glycol for possible Application in Direct Fuel Cells to Alcohol Coutinho, José William Diniz 13 March 2017 (has links) Submitted by Rosivalda Pereira (mrs.pereira@ufma.br) on 2017-05-10T17:56:20Z No. of bitstreams: 1 JoseCoutinho.pdf: 2076269 bytes, checksum: f50c622c02cff2de6c220fbd2cf046e2 (MD5) / Made available in DSpace on 2017-05-10T17:56:20Z (GMT). No. of bitstreams: 1 JoseCoutinho.pdf: 2076269 bytes, checksum: f50c622c02cff2de6c220fbd2cf046e2 (MD5) Previous issue date: 2017-03-13 / The electrooxidation of ethylene glycol and its partial oxidation products was studied in platinum-containing electrocatalysts supported on high surface carbon Vulcan XC-72, molybdenum and cadmium (90:10, 80:20, 70:30) in medium acid. All catalysts prepared were synthesized by the alcohol reduction method with 20% metallic charge on the carbon substrate. X-ray diffraction (XRD) analysis showed that the bi-metallic catalysts of PtMo / C and PtCd / C presented cubic face-centered structures and no angular displacement was observed, making it impossible to identify the molybdenum in the catalyst And revealing the absence of alloying characteristics in these catalysts. Results of Transmission Electron Microscopy (MET) revealed that bi-metallic nanoparticles have sizes between 2.0 nm and 4.0 nm. The results of cyclic voltammetry, at room temperature, showed that the presence of Mo and Cd favor the initiation of oxidation at lower potentials than those observed for platinum. However, chronoamperometry data, at a constant potential of 0.50 V and ambient temperature, did not show significant variations in the catalytic current. On the other hand, with the increase in temperature from 25 ° C to 55 ° C, differences in current were observed, with the Pt90Mo10 electrode having the best results. Data obtained by High Performance Liquid Chromatography (HPLC) showed that Glycolide is the main by-product formed by the oxidation of ethylene glycol after electrolysis at 0.50 V. / A eletrooxidação de etileno glicol e de seus produtos parciais de oxidação foi estudado em eletrocatalisadores contendo platina, suportados em carbono de alta área superficial Vulcan XC-72, em molibdênio e cadmio (90:10, 80:20, 70:30) em meio ácido. Todos os catalisadores preparados foram sintetizados pelo método de redução por álcool com 20% de carga metálica sobre o substrato de carbono. As análises por meio da técnica de Difração de Raios-X (DRX) demostraram que os catalisadores bi metálicos de PtMo/C e PtCd/C apresentaram estruturas cúbicas de face centrada e não se verificou nenhum deslocamento angular, impossibilitando a identificação do molibdênio e cádmio nos catalisadores e revelando a ausência de caráter de liga nesses eletro catalisadores. Os resultados de Micrografia Eletrônica de Transmissão (MET) revelaram que as nano partículas bi metálicas possuem tamanhos entre 2,0 nm e 4,0 nm. Os resultados de voltametria cíclica, a temperatura ambiente, mostraram que a presença de Mo e Cd favorecem o início da oxidação para potenciais mais baixos do que os observados para a platina. No entanto, os dados de cronoamperometria, a um potencial constante de 0,50 V e a temperatura ambiente, não mostraram variações significativas na corrente catalítica. Por outro lado, com o aumento da temperatura de 25 °C para 55 °C foram observados diferenças na corrente sendo o eletrodo de Pt90Mo10 com os melhores resultados. Dados obtidos por Cromatografia Líquida de Alta Eficiência (CLAE) mostraram que o Glicoladeído é o principal subproduto formado pela oxidação do etileno glicol após eletrólise a 0,50 V. Catalisadores de PtCd/C e PtMo/C Etileno Glicol Oxidação PtCd / C and PtMo / C catalysts Ethylene Glycol Oxidation Eletroquímica Eletroanalítica
72	Atmospheric Pressure Plasma Synthesis of Biocompatible Poly(ethylene glycol)-like Coatings Nisol, Bernard 26 May 2011 (has links) The role of a protein-repelling coating is to limit the interaction between a device and its physiological environment. Plasma-polymerized-PEG (pp-PEG) surfaces are of great interest since they are known to avoid protein adsorption. and cell attachment. However, in all the studies previously published in the literature, the PEG coatings have been prepared using low pressure processes. In this thesis, we synthesize biocompatible pp-PEG coatings using atmospheric pressure plasma. Two original methods are developed to obtain these pp-PEG films. 1. Atmospheric pressure plasma liquid deposition (APPLD) consists in the injection of the precursor, tetra(ethylene glycol)dimethylether (tetraglyme), by means of a liquid spray, directly in the post-discharge of an atmospheric argon plasma torch. 2. In atmospheric pressure plasma-enhanced chemical vapor deposition (APPECVD), tetraglyme vapors are brought in the post-discharge trough a heating sprinkler. The chemical composition, as well as the non-fouling properties of the APPLD and APPECVD films, are compared to those of PEG coatings synthesized by conventional low pressure plasma processes. In the first part of the study, the effect of the power on the chemical composition of the films has been investigated by infrared reflection absorption spectroscopy (IRRAS), X-ray photoelectron spectroscopy (XPS) and secondary ions mass spectroscopy (SIMS). The surface analysis reveals that for the APPECVD samples, the fragmentation of the precursor increases as the power of the treatment is increased. In other terms, the lower the plasma power is, the higher the “PEG character” of the resulting films is. Indeed, the C-O component (286.5 eV) of the XPS C 1s peak is decreasing while the hydrocarbon component (285 eV) is increasing as the power of the plasma is increased. The same conclusion can be drawn from the signature ToF-SIMS peaks (m/z = 45 (CH3OCH2+ and +CH2CH2OH), 59 (CH3OCH2CH2+), 103 (CH3(OCH2CH2)2+)) that are decreasing in the case of high power treatments. Accordingly, IRRAS measurements show that the C-O stretching band is decreasing for high power plasma deposition. This is in agreement with the observations made from the analysis of the LP PECVD coatings and from the literature. The films deposited by the APPLD process do not show the same behavior. Indeed, whatever the power injected into the discharge is, we are able to achieve films with a relatively high PEG character (83 %). The second part of this study is dedicated to the evaluation of the non-fouling properties of the coatings by exposing them to proteins (bovine serum albumin and human fibrinogen) and cells (mouse fibroblasts (L929 and MEF)) and controlling the adsorption with XPS (proteins) and SEM (cells). For the APPECVD samples, a low plasma power (30 W) leads to an important reduction of protein adsorption and cell adhesion (over 85%). However, higher-powered treatments tend to reduce the non-fouling ability of the surfaces (around 50% of reduction for a 80 W deposition). The same order of magnitude (over 90% reduction of the adsorption) is obtained for the APPLD surfaces, whatever is the power of the treatment. Those results show an important difference between the two processes in terms of power of the plasma treatment, and a strong relationship between the surface chemistry and the adsorption behavior: the more the PEG character is preserved, the more protein-repellent and cell-repellent is the surface. / Le rôle d’une couche empêchant l’adsorption de protéines est de limiter les interactions entre un implant et le milieu physiologique auquel il est exposé. Les films de poly(éthylène glycol) polymérisés par plasma (pp-PEG) sont d’intérêt majeur car ils sont connus pour empêcher l’adsorption de protéines ainsi que l’attachement cellulaire. Cependant, dans toutes les études publiées précédemment, les couches de type PEG ont été réalisées sous vide. Dans cette thèse de doctorat, nous synthétisons des couches de type pp-PEG biocompatibles par plasmas à pression atmosphérique. A cette fin, deux méthodes originales ont été développées. 1. La première méthode consiste en l’injection du précurseur, le tetra(éthylène glycol) diméthyl éther (tetraglyme), en phase liquide, en nébulisant ce dernier au moyen d’un spray, directement dans la post-décharge d’une torche à plasma atmosphérique fonctionnant à l’argon. En anglais, nous appelons ce procédé « Atmospheric pressure plasma liquid deposition (APPLD) ». 2. Dans la deuxième méthode, appelée en anglais « Atmospheric pressure plasma-enhanced chemical vapor deposition (APPECVD)», le tetraglyme est amené en phase vapeur dans la post-décharge, au moyen d’un diffuseur chauffant. La composition chimique des dépôts de type APPLD et APPECVD, ainsi que leurs propriétés d’anti-adsorption sont évaluées, et comparées aux dépôts pp-PEG obtenus par les méthodes à basse pression conventionnelles. Dans la première partie de cette étude, nous nous focalisons sur la composition chimique des films déposés, et plus particulièrement sur l’influence de la puissance injectée dans le plasma sur cette composition chimique. A cette fin, nous avons fait appel à des techniques d’analyse telles que la spectroscopie de réflexion-absorption infrarouge (IRRAS), la spectroscopie des photoélectrons X (XPS) et la spectrométrie de masse des ions secondaires (SIMS). Il en ressort que les films de type APPECVD perdent progressivement leur « caractère PEG » à mesure que la puissance de la décharge plasma est élevée. Cela serait dû à une plus grande fragmentation du précurseur dans la post-décharge d’un plasma plus énergétique. Cette tendance est cohérente avec ce que nous avons observé pour les dépôts à basse pression ainsi que dans la littérature. Dans le cas des films de type APPLD, un tel comportement n’a pas été mis en évidence : quelle que soit la puissance dissipée dans le plasma, les films présentent un « caractère PEG » relativement élevé. La deuxième partie de cette thèse est dédiée à l’évaluation des propriétés d’anti-adsorption des films synthétisés, en les exposant à des protéines (albumine de sérum bovin et fibrinogène humain) et des cellules (fibroblastes de souris, L929 et MEF). L’adsorption de protéines est contrôlée par XPS tandis que l’attachement cellulaire est contrôlé par imagerie SEM. Pour les échantillons de type APPECVD, un dépôt à faible puissance (30 W) mène à une importante réduction de l’adsorption de protéines et de cellules (> 85%) tandis qu’à de plus hautes puissances (80 W), l’anti-adsorption est sensiblement diminuée (50% de réduction). Dans le cas des dépôts de type APPLD, quelle que soit la puissance du plasma, une forte diminution de l’adsorption de protéines et de cellules est observée (> 90 %). Ces résultats montrent une différence majeure entre les deux procédés quant à l’influence de la puissance du plasma ainsi qu’une forte relation entre la composition chimique de la surface synthétisée et son pouvoir d’anti-adsorption : plus le « caractère PEG » du dépôt est conservé, plus la surface empêchera l’interaction avec les protéines et les cellules. plasma polymerisation atmospheric pressure plasma deposition cell adhesion biocompatibility poly(ethylene glycol) (PEG) protein-repelling surfaces tetra(ethyleneglycol) dimethyl ether
73	Growth and Biofilm Formation by Staphylococcus Epidermidis and Other Relevant Contaminant Bacteria During Storage of Platelet Concentrates Greco, Carey Anne 28 September 2011 (has links) Coagulase negative staphylococci (CoNS) are the most prevalent bacterial contaminants of platelet concentrates (PCs), and have been implicated in severe and fatal transfusion reactions. Of this group, Staphylococcus epidermidis is most frequently identified. The preliminary objective of this thesis was to confirm that S. epidermidis could form biofilms under platelet storage conditions. This was achieved using a modified crystal violet staining assay to detect plastic-adherent bacterial cells and examination of attachment processes by scanning electron microscopy. A collection of CoNS isolated from PCs obtained from reportedly healthy donors was then assessed for biofilm-forming potential at the genetic and phenotypic level. Despite the presumable commensal origin of these isolates, a high proportion of S. epidermidis strains displayed a biofilm positive phenotype. The threat of S. epidermidis biofilm formation during platelet storage identified herein signifies that any alterations made to platelet storage protocols should be evaluated with consideration of this risk. The advent of platelet additive solutions (PASs) as an alternative to plasma for PC storage provides a relevant example, since little is known about the effect of PAS on contaminant bacteria, and vice versa. Growth and biofilm formation by S. epidermidis and the Gram-negative bacterium Serratia liquefaciens were measured in PAS- or plasma-PCs over 5 days, simulating standard platelet storage conditions, after initial inoculation with low, clinically relevant bacterial concentrations. Assays for platelet quality were performed simultaneously. Only S. liquefaciens exhibited a slower doubling time in plasma-PCs than in PAS-PCs. Biofilm formation by both species was reduced during storage in PAS-PCs, increasing bacteria availability for detection. Although S. liquefaciens adversely affected platelet quality in both media, S. epidermidis contamination did not. Ultimately, culture-based detection remains the earliest indicator of bacterial presence in PAS-PCs. Lastly, since formation of platelet-bacteria aggregates is largely based on receptor-ligand interactions, it was postulated that biofilm formation by contaminant bacteria could be abrogated by receptor shielding. Methoxypoly(ethylene glycol) was applied to covalently modify the platelet surface using a process termed ‘PEGylation’. It is herein demonstrated that PEGylation of PCs inoculated with S. epidermidis results in significantly reduced bacterial binding and biofilm formation during platelet storage. Staphylococcus epidermidis biofilms coagulase negative staphylococci Serratia liquefaciens platelet concentrates platelet additive solution poly(ethylene glycol) blood product contamination
74	Growth and Biofilm Formation by Staphylococcus Epidermidis and Other Relevant Contaminant Bacteria During Storage of Platelet Concentrates Greco, Carey Anne 28 September 2011 (has links) Coagulase negative staphylococci (CoNS) are the most prevalent bacterial contaminants of platelet concentrates (PCs), and have been implicated in severe and fatal transfusion reactions. Of this group, Staphylococcus epidermidis is most frequently identified. The preliminary objective of this thesis was to confirm that S. epidermidis could form biofilms under platelet storage conditions. This was achieved using a modified crystal violet staining assay to detect plastic-adherent bacterial cells and examination of attachment processes by scanning electron microscopy. A collection of CoNS isolated from PCs obtained from reportedly healthy donors was then assessed for biofilm-forming potential at the genetic and phenotypic level. Despite the presumable commensal origin of these isolates, a high proportion of S. epidermidis strains displayed a biofilm positive phenotype. The threat of S. epidermidis biofilm formation during platelet storage identified herein signifies that any alterations made to platelet storage protocols should be evaluated with consideration of this risk. The advent of platelet additive solutions (PASs) as an alternative to plasma for PC storage provides a relevant example, since little is known about the effect of PAS on contaminant bacteria, and vice versa. Growth and biofilm formation by S. epidermidis and the Gram-negative bacterium Serratia liquefaciens were measured in PAS- or plasma-PCs over 5 days, simulating standard platelet storage conditions, after initial inoculation with low, clinically relevant bacterial concentrations. Assays for platelet quality were performed simultaneously. Only S. liquefaciens exhibited a slower doubling time in plasma-PCs than in PAS-PCs. Biofilm formation by both species was reduced during storage in PAS-PCs, increasing bacteria availability for detection. Although S. liquefaciens adversely affected platelet quality in both media, S. epidermidis contamination did not. Ultimately, culture-based detection remains the earliest indicator of bacterial presence in PAS-PCs. Lastly, since formation of platelet-bacteria aggregates is largely based on receptor-ligand interactions, it was postulated that biofilm formation by contaminant bacteria could be abrogated by receptor shielding. Methoxypoly(ethylene glycol) was applied to covalently modify the platelet surface using a process termed ‘PEGylation’. It is herein demonstrated that PEGylation of PCs inoculated with S. epidermidis results in significantly reduced bacterial binding and biofilm formation during platelet storage. Staphylococcus epidermidis biofilms coagulase negative staphylococci Serratia liquefaciens platelet concentrates platelet additive solution poly(ethylene glycol) blood product contamination
75	The effects of tensile loading and extracellular environmental cues on fibroblastic differntiation and extracellular matrix production by mesenchymal stem cells Doroski, Derek M. 22 March 2011 (has links) Ligament/tendon tissue engineering has the potential to provide therapies that overcome the limitations of incomplete natural healing responses and inadequate graft materials. While ligament/tendon fibroblasts are an obvious choice of cell type for these applications, difficulties associated with finding a suitable cell source have limited their utility. Mesenchymal stem cells/marrow stromal cells (MSCs) are seen as a viable alternative since they can be harvested through routine medical procedures and can be differentiated toward a ligament/tendon fibroblast lineage. Further study is needed to create an optimal biomaterial/biomechanical environment for ligament/tendon fibroblastic differentiation of MSCs. The overall goal of this dissertation was to improve the understanding of the role that biomechanical stimulation and the biomaterial environment play, both independently and combined, on human MSC (hMSC) differentiation toward a ligament/tendon fibroblast phenotype. Specifically, the effects of cyclic tensile stimuli were studied in a biomaterial environment that provided controlled presentation of biological moieties. The influence of an enzymatically-degradable biomaterial environment on hMSC differentiation was investigated by creating biomaterials containing enzymatically-cleavable moieties. The role that preculture may play in tensile responses of hMSCs was also explored. Together, these studies provided insights into the contributions of the biomaterial and biomechanical environment to hMSC differentiation toward a ligament/tendon fibroblast phenotype. GGGLGPAGGK Matrix metalloproteinase Oligo(poly(ethylene glycol) fumarate) Hydrogel Mesenchymal stem cells Differentiation Ligament prostheses Tendons Tissue engineering Biomechanics
76	Layer-by-layer Self-assembly Membranes for Solvent Dehydration by Pervaporation Zhang, Ying January 2014 (has links) In this study, polyelectrolyte membranes were prepared by layer-by-layer self-assembly on top of an interfacially polymerized polyamide substrate, and these thin-film-composite membranes were studied for pervaporative dehydration of ethylene glycol, ethanol and isopropanol. The performance of composite membranes based on polyethylenimine/poly(acrylic acid) (PEI/PAA) multilayers on a polyamide substrate showed good selectivity and stability for ethylene glycol dehydration. In order to understand the formation process of the polyelectrolyte multilayers, the growth of polyelectrolyte multilayers fabricated on the inner surface of cuvette was investiagted. The membrane surface became increasingly hydrophilic with an increase in the number of polyelectrolyte double layers, which favored water permeation for pervaporative dehydration of organic solvents. Water contact angle on the membrane surface decreased from 68?? to 20?? when 7 polyelectrolyte bilayers were deposited on the polyamide substrate. Although the (PEI/PAA) based polyelectrolyte membranes showed good performance for dehydration of ethylene glycol, these membranes did not perform well for the dehydration of ethanol and isopropanol at relatively high feed alcohol concentrations. This was found to be caused by insufficient stability of PEI/PAA bilayers and the polyamide substrate in the ethanol and isopropanol. To improve the performance of the composite membranes for dehydration of ethanol and isopropanol, the outermost surface layer was deposited with PEI, followed by crosslinking. A further improvement in the membrane selectivity was accomplished by substituting the PEI with partially protonated chitosan in the last few polyelectrolyte bilayers during membrane fabrication. It was demonstrated that using interfacially polymerized polyamide membrane as a substrate, polyelectrolyte membranes with less than 8 bilayers could be fabricated for the dehydration of alcohol and diol. This represents a siginificant advancement as a large number of polyelectrolyte bilayers (as many as 60) are often needed. Glutaraldehyde crosslinked polyelectrolyte self-assembled membranes comprising of chitosan and PAA were also prepared for isopropanol/water separation. The resulting membrane showed stable performance with good permeation flux and separation factor. The effects of crosslinking conditions (e.g., concentration and temperature of crosslinking agent, and crosslinking time) on the membrane performance were studied. Alternatively, using PEI as polycation, when anionic PAA was substituted with alginate in the last few polyelectrolyte bilayers during membrane fabrication, stable membranes with a good performance were obtained without the need of chemical crosslinking. The polyethylenimine/alginate self-assembly membranes showed good selectivity and stability for dehydration of ethanol. For instance, a permeation flux of 0.24 kg/(??? h) and a separation factor of 206 were obtained at room temperature at 10 wt% feed water concentration with a membrane comprising of 10 double layers of polyelectrolytes.
77	Lamination of Organic Solar Modules Kalldin, Sofie January 2014 (has links) As the Worlds energy demand is increasing we need more of our energy to be generated from resources that affect the climate as little as possible. Solar power could be the solution if there were solar panels with a less energy demanding production than the established silicon based solar modules. Printable organic solar cells will enable a cheap production process, thus they are mainly made out of polymers in solution. However, to be able to decrease the total cost of the solar modules the commonly used indium tin oxide (ITO) for the transparent electrode needs to be replaced by a less expensive material. If the cheap, high conductive and transparent polymer poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) (PEDOT:PSS) could replace ITO the cost of organic solar modules would significantly decrease. For PEDOT:PSS to be able to replace ITO there are requirements that have to be met. The transparent electrode needs to be apart from transparent, highly conductive, have a low contact resistance to the other materials in the organic solar cell and be printable. In this study it has been shown that the PEDOT:PSS film with Zonyl and Diethylene Glycol (DEG) as an secondary dopant, is capable of laminating to thin films made out of PEDOT:PSS, metal or a polymer fullerene blend. The contact resistances between two PEDOT:PSS films and PEDOT:PSS film and a metal film proved to be low. When laminating to a metal film an interlayer of Silver Nano Wires (AgNW) was needed to achieve a low contact resistance. Organic solar modules Lamination PEDOT:PSS Ethylene Glycol (EG) Diethylene Glycol (DEG) Polyethylene Glycol (PEG) Roll to roll process (R2R)
78	Growth and Biofilm Formation by Staphylococcus Epidermidis and Other Relevant Contaminant Bacteria During Storage of Platelet Concentrates Greco, Carey Anne 28 September 2011 (has links) Coagulase negative staphylococci (CoNS) are the most prevalent bacterial contaminants of platelet concentrates (PCs), and have been implicated in severe and fatal transfusion reactions. Of this group, Staphylococcus epidermidis is most frequently identified. The preliminary objective of this thesis was to confirm that S. epidermidis could form biofilms under platelet storage conditions. This was achieved using a modified crystal violet staining assay to detect plastic-adherent bacterial cells and examination of attachment processes by scanning electron microscopy. A collection of CoNS isolated from PCs obtained from reportedly healthy donors was then assessed for biofilm-forming potential at the genetic and phenotypic level. Despite the presumable commensal origin of these isolates, a high proportion of S. epidermidis strains displayed a biofilm positive phenotype. The threat of S. epidermidis biofilm formation during platelet storage identified herein signifies that any alterations made to platelet storage protocols should be evaluated with consideration of this risk. The advent of platelet additive solutions (PASs) as an alternative to plasma for PC storage provides a relevant example, since little is known about the effect of PAS on contaminant bacteria, and vice versa. Growth and biofilm formation by S. epidermidis and the Gram-negative bacterium Serratia liquefaciens were measured in PAS- or plasma-PCs over 5 days, simulating standard platelet storage conditions, after initial inoculation with low, clinically relevant bacterial concentrations. Assays for platelet quality were performed simultaneously. Only S. liquefaciens exhibited a slower doubling time in plasma-PCs than in PAS-PCs. Biofilm formation by both species was reduced during storage in PAS-PCs, increasing bacteria availability for detection. Although S. liquefaciens adversely affected platelet quality in both media, S. epidermidis contamination did not. Ultimately, culture-based detection remains the earliest indicator of bacterial presence in PAS-PCs. Lastly, since formation of platelet-bacteria aggregates is largely based on receptor-ligand interactions, it was postulated that biofilm formation by contaminant bacteria could be abrogated by receptor shielding. Methoxypoly(ethylene glycol) was applied to covalently modify the platelet surface using a process termed ‘PEGylation’. It is herein demonstrated that PEGylation of PCs inoculated with S. epidermidis results in significantly reduced bacterial binding and biofilm formation during platelet storage. Staphylococcus epidermidis biofilms coagulase negative staphylococci Serratia liquefaciens platelet concentrates platelet additive solution poly(ethylene glycol) blood product contamination
79	The secret life of small alcohols : the discovery and exploitation of fragmentation, adduct formation and auto-modification phenomena in differential ion mobility spectrometry leading to next-generation toxicity screening Ruszkiewicz, Dorota M. January 2016 (has links) The research presented in this thesis started with the idea to study alcohols as modifiers and dopants in differential ion mobility spectrometry (d-IMS) to produce complicated chemical signatures to explore a concept of chemical labels for product security application. D-IMS is a gas phase atmospheric pressure separation and detection technique which distinguishes compounds based on differences in their ions mobility as their travel under a low and high electric field. The hypothesis was that alcohols will form typical d-IMS products such as protonated monomers and proton bound cluster ions. However, the very first experiments revealed unexpected phenomena which included changes in the mobility of ions over a narrow range of concentrations that could not be explained by existing theory. Another observation was the apparent regeneration of reactant ions. It became evident that the observed phenomena had not been described in the open literature and that addressing the research-questions that were being raised would be essential for the determination of alcohols by d-IMS and its use in medical applications for toxicity screening and monitoring of alcohols. The above discovery shifted the research objective towards a fundamental and comprehensive study on the behaviour of alcohols in d-IMS. This thesis describes designed experiments and constructed systems allowing the efficient study of effect of concentration, electric field and temperature on the d-IMS responses of alcohols. The results of those studies demonstate: extensive fragmentation of alcohols, including previously undescribed fragmentation patterns with regeneration of the hydrated proton; new phenomena of adduct ion formation within the d-IMS drift tube, observed in the case of methanol within a narrow range of concentration; and self-modification of the alpha function of alcohols. This knowledge was exploited by developing an non-invasive analytical method for recovery, separation and detection of toxins from human saliva (including alcohols, diols and GHB) using TD-GC-d-IMS (thermal desorption - gas chromatography d-IMS) within a full range of toxicological concentration levels. 547
80	Simulação de poli(etileno glicol) em água por dinâmica molecular / Gaspar, Renato Tadeu. January 2007 (has links) Orientador: Eloi da Silva Feitosa / Banca: Leo Degreve / Banca: Luiz Carlos Gomide Freitas / Banca: José Roberto Ruggiero / Banca: Marinômio Lopes Cornélio / Resumo: O Poli(etileno glicol) (PEG) é um polímero sintético cujas características tem despertado grande interesse em diversas áreas. Suas aplicações podem ser vistas nas mais variadas áreas, desde biotecnologia e medicina até aplicações industriais e cosméticos. Alguns aspectos físicos como a estrutura adotada por esse polímero em diferentes solventes e detalhes sobre a interação entre essas moléculas ainda necessitam de maiores esclarecimentos, o que o torna objeto de intensa investigação. Essa tese visa desenvolver um modelo para moléculas de PEG, que possa ser utilizado em experimentos de dinâmica molecular. Resultados de simulações com esse modelo foram comparados a dados experimentais presentes na literatura, de forma a verificar o comportamento do modelo em diferentes condições, avaliando assim sua adequação. Os valores de densidade, obtidos dos sistemas simulados, apresentaram erro máximo de 1,14% para concentrações de até 50% de PEG400. A densidade do sistema em função da temperatura concorda com os dados da literatura, mantendo um erro fixo de 0,35%, que está relacionado com a concentração de 50% utilizada nessa simulação. A estrutura helicoidal, apresentada pelas moléculas de PEG ao final do processo de preparação dos modelos, é perdida rapidamente em todas as diferentes condições em que o sistema foi simulado, indicando que tal estrutura é energeticamente desfavorável em água. Com o aumento da concentração de PEG, as seguintes estruturas foram encontradas: moléculas de PEG livres em solução em concentrações inferiores a 5%, aglomerados de PEG entre 5 e 50%, com uma transição gradual entre uma estrutura e outra. Os resultados obtidos para concentrações acima de 50% não são conclusivos. Seguindo o procedimento aplicado ao modelo inicial, de PEG400, foi desenvolvido ...(Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Poly(ethylene glycol) (PEG) is a synthetic polymer whose characteristics have attracted great interest in different fields. It has been applied in very different areas, from biotechnology and medicine to industry and cosmetics. Physical aspects like the structure PEG assumes in different solvent and details on the interaction between these polymers still lack clarity, make PEG an object of intense investigation. This Thesis aims do develop a model for PEG molecules that can be used in molecular dynamic simulations. Results of simulations using this model were compared to published experimental data, in order to investigate the behavior of the model under different conditions to evaluate its validity. The density values obtained from the simulations exhibit a maximum error of 1.14% for PEG400 concentrations up to 50%. The system density as a function of temperature agrees with experimental data from the literature within an error of 0.35% for the 50% PEG in the simulation. The helicoidal structure assumed by the PEG molecules at the end of the procedure of the model preparation is quickly lost under every simulation condition, thus indicating that the helicoidal structure is not energetically favorable for PEG in water. As PEG concentration is increased, the following structures were found: free PEG molecules below ca 5%, PEG clusters from ca 5-50%, with a gradual transition from one structure to another. The results for concentrations higher than 50% are not conclusive. Following the procedure applied to the initial PEG400 model, a second model was developed, almost four times larger, and used to investigate possible molecular effects capable to induce phase thermoseparation. The transition from different system states took place on average temperatures between 423.3 K and 424.1 K at the average pressure of 8.98 Bar. / Doutor Dinamica molecular. Coloides. Polietileno. Biofísica. Biologia molecular. Polimeros inorganicos. Molecular dynamic. eng Polymer. eng Poly(ethylene glycol) eng

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