Global ETD Search

211	Negative energy elasticity and a model for the behavior of the residual strain in doubly cross-linked gels fabricated by shear strain You, Therese January 2020 (has links) Doubly cross-linked gels were fabricated based on tetra-poly(ethylene glycol) (Tetra-PEG) by shear strain. These are gels with two network structures present in the same polymeric network. The second network structure is introduced by applying a mechanical field to the first natural network structure. These doubly cross-linked gels indicated a negative energy elasticity supporting earlier findings where the energy elasticity was found significantly negative for Tetra-PEG gel. Acquired results indicate implications for past research on the elasticity of polymer gels where the energy contribution was approximated to zero. Obtained results also indicated that the modulus of rigidity for the doubly cross-linked gels is constant regardless of applied shear strain during fabrication. This would indicate that the same second network structure is formed for the interval of 25-800% applied shear strain. The residual strain for the fabricated gels can be well-described using an exponential fitting of the apparent shear modulus of the first network structure and an expression derived from the two-network theory and classic rubber theory. These theories also seem to predict the experimental residual strains for lower strain regions (<100%) quite well. However for larger strain regions (>100%) non-linear effects seem to affect the results causing a deviation. A slight increased modulus of rigidity was noted for the doubly cross-linked gels compared to the regular Tetra-PEG gel. However as the reproducibility of the concluded measurements could not be confirmed during this thesis the results are not conclusive and only indicate the conclusions mentioned above. Polymer gel Tetra-PEG hydrogels doubly cross-linked gels shear modulus energy elasticity Engineering and Technology Teknik och teknologier
212	Material Properties and Aesthetic Qualities of Gels Mayer, Kerstin 30 June 2022 (has links) We live in a time of many challenges. The ‘Great Acceleration’ (Steffen et al., 2015) is a trend that can be observed in numerous fields in our world: be it the development of CO2 emissions, the land use or the enormous amount of produced plastics accompanied by massive environmental pollution. This ‘phenomenon’ is obviously directly linked to the way we live and how our society works. To meet these developments, we need to move away from the big, prone concepts that got us here in the first place, and instead build on a variety of dynamic and changing solutions. info:eu-repo/classification/ddc/620 ddc:620
213	Développement d’hydrogels biocompatibles à base de cyclodextrines pour l’encapsulation et le relargage de médicaments Lecluse, Margaux 07 1900 (has links) Les hydrogels sont des matériaux aux propriétés modulables dont la dégradation peut être contrôlée. Du fait de leur biocompatibilité, ils peuvent être utilisés afin de protéger les médicaments labiles et ainsi favoriser l’administration de traitements médicaux, d’où l’intérêt croissant de développer ces matériaux. Depuis quelques années, ils font l’objet de nombreuses recherches, que ce soit en ingénierie tissulaire, détection de mouvement, régénération de tissus ou pour le relargage de médicaments. Ce projet de thèse porte sur la formation d’hydrogels à base d’α-cyclodextrine et de polyéthylène glycol 20K ainsi que sur l’étude de leur capacité de relargage de principes actifs. Ces composés ont la capacité de former des complexes d’inclusion, créant ainsi un collier de perle, appelés pseudopolyrotaxane. Ensuite, ils seront modifiés pour créer des hydrogels de polyrotaxanes grâce à l’ajout de groupement bloquants. Finalement, nous formerons des hydrogels à point de réticulations glissant après avoir relié deux polyrotaxanes par leur macrocycle. À l’aide d’études rhéologiques, nous avons montré une amélioration des propriétés mécaniques des hydrogels proportionnelle à l’apport de liaisons chimique. Les groupements bloquants permettent d’éviter la désinclusion tandis que les réticulations apportent un effet poulie, les rendant exceptionnellement élastique. Ces hypothèses sont validées par les études structurales. Et nos hydrogels se sont révélés non toxiques pour les cellules humaines et ces résultats confirment leur biocompatibilité. Les hydrogels de pseudopolyrotaxanes sont les plus écologiques et les plus appropriés pour une application locale cutanée. Les hydrogels de polyrotaxanes, plus stables, peuvent être utilisés pour des applications locales prolongées ou par injection. Cependant, nos hydrogels de polyrotaxanes réticulés devront être modifiés afin de permettre un relargage contrôlé, car leur extrême stabilité pourrait entraver leur dégradation lors d'une injection sous-cutanée malgré leurs propriétés mécaniques exceptionnelles. / Hydrogels are materials with tunable properties whose degradation can be controlled. Because of their biocompatibility, they can be used to protect labile drugs and thus facilitate the administration of medical treatments, hence the growing interest in developing these materials. In recent years, they have been the subject of numerous studies, whether in tissue engineering, motion sensing, tissue regeneration or drug delivery. This project focuses on the formation of hydrogels based on α-cyclodextrin and polyethylene glycol 20K and the study of their drug release capacity. These compounds can form inclusion complexes, forming a pearl necklace called pseudopolyrotaxane. They will then be modified to form polyrotaxane hydrogels by adding blocking groups. Finally, we will form hydrogels with sliding cross-linking points after linking two polyrotaxanes through their macrocycle. Through rheological studies, we have demonstrated an improvement in the mechanical properties of the hydrogels proportional to the introduction of chemical bonds. Blocking groups prevent desorption, while cross-linking provides a pulley effect, making them exceptionally elastic. These hypotheses are supported by structural studies. Our hydrogels have been shown to be non-toxic to human cells, confirming their biocompatibility. Pseudopolyrotaxane hydrogels are the most environmentally friendly and suitable for local cutaneous application. Polyrotaxane hydrogels are more stable and can be used for prolonged local applications or by injection. However, our cross-linked polyrotaxane hydrogels will need to be modified to allow controlled release, as their extreme stability could hinder their degradation during subcutaneous injection, despite their exceptional mechanical properties. cyclodextrine pseudopolyrotaxane polyrotaxane relargage de médicament sliding gels cyclodextrin drug release Chemistry / Chimie (UMI : 0485)
214	Development, Characterization, and Fundamental Studies on Molecular Ionic Composites and PBDT Hydrogels Zanelotti, Curt Joseph 28 January 2022 (has links) This dissertation aims to develop, characterize, and fundamentally understand a new class of materials termed "molecular ionic composites" (MICs). MICs show promise as next-generation solid electrolytes for batteries. MICs form when mixing a rigid polyanion with purely ionic fluids, and they behave mechanically as a solid but contain a high density of ions that move nearly as in a neat liquid. Specifically, prototypical MICs are based on solutions of the rigid-rod polyelectrolyte poly(2,2'-disulfonyl-4,4'-benzideneterephthalamide) (PBDT), which forms a double helix, combined with imidazolium-based ionic liquids (ILs). The IL comprises 75-97 wt% of the final solid, even though the Young's modulus can reach ~ 2 GPa at 80 wt% IL. We propose that these properties are driven by a biphasic internal structure in MICs corresponding to IL-rich "puddles" (an interconnected liquid phase) and PBDT-IL associated "bundles" where IL ions form the collective electrostatic associations that cause the MICs to be a solid. Through this dissertation I will discuss a wide variety of MICs that have been created through the use of two different formation processes, the "ingot" method and the "solvent casting" method, which allow for the use of many different ionic fluid sources to further tune MIC properties. The following chapters build to the fundamental knowledge and our current understanding of the wide variety of materials that can be created from PBDT and IL. / Doctor of Philosophy / Battery electrolytes, biosensors, and hydrogels all depend on new materials for next-generation applications. For these new materials to be used characterization on the interactions, morphological restrictions, and/or what unique internal structures used to generate their properties must be performed. Through This analysis using common polymeric characterization techniques these materials can be further optimized. This dissertation highlights a new class of materials termed "molecular ionic composites" (MICs) which are formed from a rigid double helical polymer, poly(2,2'-disulfonyl-4,4'-benzideneterephthalamide) (PBDT), and fluids composed entirely of ions, including ionic liquids (ILs). These composite systems feature a unique combination of properties including high thermal stability, mechanical stability, and excellent ionic conductivity, all of which are highly tunable through the amount of PBDT incorporated or the fluid ion types. Chapters 3, 4, 5, and 6 present fundamental investigations of MICs to determine how tunable they are, the processes by which they form, and the various ways we can fabricate them. Chapter 7 describes the creation of another impressive material formed from PBDT-low-polymer-content hydrogels. These studies are intended to provide deeper understanding of the behaviors of these unique materials and how they may be used in the future. Polymer Electrolytes Ion Gels Rigid-rod Polyelectrolytes NMR Self-diffusion Variable Temperature Ion Transport Hydrogel Self-assembly
215	Development and Characterization of Advanced Polymer Electrolyte for Energy Storage and Conversion Devices Wang, Ying 09 January 2017 (has links) Among the myraid energy storage technologies, polymer electrolytes have been widely employed in diverse applications such as fuel cell membranes, battery separators, mechanical actuators, reverse-osmosis membranes and solar cells. The polymer electrolytes used for these applications usually require a combination of properties, including anisotropic orientation, tunable modulus, high ionic conductivity, light weight, high thermal stability and low cost. These critical properties have motivated researchers to find next-generation polymer electrolytes, for example ion gels. This dissertation aims to develop and characterize a new class of ion gel electrolytes based on ionic liquids and a rigid-rod polyelectrolyte. The rigid-rod polyelectrolyte poly (2,2'-disulfonyl-4,4'-benzidine terephthalamide) (PBDT) is a water-miscible system and forms a liquid crystal phase above a critical concentration. The diverse properties and broad applications of this rigid-rod polyelectrolyte may originate from the double helical conformation of PBDT molecular chains. We primarily develop an ionic liquid-based polymer gel electrolyte that possesses the following exceptional combination of properties: transport anisotropy up to 3.5×, high ionic conductivity (up to 8 mS cm⁻¹), widely tunable modulus (0.03 – 3 GPa) and high thermal stability (up to 300°C). This unique platform that combines ionic liquid and polyelectrolyte is essential to develop more advanced materials for broader applications. After we obtain the ion gels, we then mainly focus on modifying and then applying them in Li-metal batteries. As a next generation of Li batteries, the Li-metal battery offers higher energy capacity compared to the current Li-ion battery, thus satisfying our requirements in developing longer-lasting batteries for portable devices and even electric vehicles. However, Li dendrite growth on the Li metal anode has limited the pratical application of Li-metal batteries. This unexpected Li dendrite growth can be suppressed by developing polymer separators with high modulus (~ Gpa), while maintaining enough ionic conductivity (~ 1 mS/cm). Here, we describe an advanced solid-state electrolyte based on a sulfonated aramid rigid-rod polymer, an ionic liquid (IL), and a lithium salt, showing promise to make a breakthrough. This unique fabrication platform can be a milestone in discovering next-generation electrolyte materials. / Ph. D. Polymer Electrolytes Ion Gels Liquid Crystalline Polymer Rigid-rod Polyelectrolytes Molecular Alignment Ion Transport Polymer Characterization Li-metal Battery
216	Improved Sterilization of Sensitive Biomaterials with Supercritical Carbon Dioxide at Low Temperature Bernhardt, Anne, Wehrl, Markus, Paul, Birgit, Hochmuth, Thomas, Schumacher, Matthias, Schütz, Kathleen, Gelinsky, Michael 20 January 2016 (has links) (PDF) The development of bio-resorbable implant materials is rapidly going on. Sterilization of those materials is inevitable to assure the hygienic requirements for critical medical devices according to the medical device directive (MDD, 93/42/EG). Biopolymer-containing biomaterials are often highly sensitive towards classical sterilization procedures like steam, ethylene oxide treatment or gamma irradiation. Supercritical CO2 (scCO2) treatment is a promising strategy for the terminal sterilization of sensitive biomaterials at low temperature. In combination with low amounts of additives scCO2 treatment effectively inactivates microorganisms including bacterial spores. We established a scCO2 sterilization procedure under addition of 0.25% water, 0.15% hydrogen peroxide and 0.5% acetic anhydride. The procedure was successfully tested for the inactivation of a wide panel of microorganisms including endospores of different bacterial species, vegetative cells of gram positive and negative bacteria including mycobacteria, fungi including yeast, and bacteriophages. For robust testing of the sterilization effect with regard to later application of implant materials sterilization all microorganisms were embedded in alginate/agarose cylinders that were used as Process Challenge Devices (PCD). These PCD served as surrogate models for bioresorbable 3D scaffolds. Furthermore, the impact of scCO2 sterilization on mechanical properties of polysaccharide-based hydrogels and collagen-based scaffolds was analyzed. The procedure was shown to be less compromising on mechanical and rheological properties compared to established low-temperature sterilization methods like gamma irradiation and ethylene oxide exposure as well as conventional steam sterilization. Cytocompatibility of alginate gels and scaffolds from mineralized collagen was compared after sterilization with ethylene oxide, gamma irradiation, steam sterilization and scCO2 treatment. Human mesenchymal stem cell viability and proliferation were not compromised by scCO2 treatment of these materials and scaffolds. We conclude that scCO2 sterilization under addition of water, hydrogen peroxide and acetic anhydride is a very effective, gentle, non-cytotoxic and thus a promising alternative sterilization method especially for biomaterials. Medizinprodukt Sterilisationsverfahren Biomaterialien TU Dresden Publikationsfonds Collagens Gels Biomaterials Mechanical properties Bacterial spores Viscosity Anhydrides Bacteria Technical University Dresden Publication funds
217	Gels d'émulsions à base d'huiles cristallisables : mécanismes de formation et propriétés rhéoloqiques Thivilliers, Florence 17 September 2007 (has links) (PDF) La formation de cristaux dans la phase dispersée d'une émulsion huile-dans-eau fait apparaître des irrégularités ou aspérités aux interfaces pouvant entraîner des modifications rhéologiques spectaculaires comme le passage d'un état fluide à un état solide. Nous montrons que la gélification des émulsions par voie thermique peut être attribuée à deux mécanismes : la coalescence partielle, qui permet grâce aux cristaux interfaciaux deformer des liens irréversibles entre gouttes, et le «jamming » qui est un phénomène de blocage dû aux aspérités empêchant le mouvement relatif des surfaces au contact. Sur des systèmes modèles, nous établissons que les mécanismes et les cinétiques de gélification sont contrôlés par la proportion d'huile cristallisée, le diamètre moyen des gouttes et la composition de l'interface. Nous montrons en particulier que la coalescence partielle peut être décrite comme un processus de percolation nécessitant des contacts de type « solide contre liquide » entre les gouttes. Nous montrons ensuite que la mise en écoulement des émulsions ou des gels peut conduire à deux situations limites : la séparation macroscopique des phases (ou barattage) ou bien la persistance d'un gel de plus faible connectivité. Nous étudions l'influence des paramètres qui sont à l'origine de cette évolution topologique. La variété des états accessibles rend ces matériaux très attractifs pour les secteurs de la cosmétique et l'agroalimentaire. [PHYS:COND] Physics/Condensed Matter émulsion coalescence partielle jamming barattage huile cristallisable Matière Grasse Laitière Anhydre (MGLA) rhéologie des gels interface
218	On the Modelling of Mechanical Dewatering in Papermaking Lobosco, Vinicius January 2004 (has links) Most of the water fed into a paper machine is removedmechanically in the forming and press sections. One of thefactor which has an important influence on mechanicaldewatering, i.e. in both forming and pressing, is thestress-strain behaviour of the fibre network. The focus of this thesis is on the development of improvedmathematical descriptions of the stress-strain behaviourexhibited by fibre networks in the forming and press sections.The first part of the thesis presents a physically based modelof the forming and densification of fibre mats in twin-wireformers. The model can calculate the ecect of the applicationof a varied load through the forming section. It was developedfrom mass and momentum balances of the fibre and liquid phases,the fibre mat stress-porosity relation and an expression forthe permeability as a function of the porosity. The fibre-matstress-porosity relation used is rate-independent and presentshysteresis. Simulations have been conducted to study theeffects of roll pressure, blade pulses, wire tension andbeating. The effect of sequential blade pressure pulses afterthe forming roll on the dewatering and the concentrationgradients could be characterised. The simulations alsoexhibited rewetting by expansion when the fibre mats left theforming roll. Increasing wire tension resulted in increaseddewatering, but the rate of increase diminished rapidly withincreasing tension. The simulation results also indicated thatbeating has a large influence on dewatering. The second part of the thesis presents two models of therate-dependent stress-strain behaviour of the fibre networkthat is observed in wet pressing. The first model was based onthe approach pioneered by Perzyna (1966) for strain-ratedependent plasticity and was quite satisfactory for calculatingthe stress-strain behaviour of the fibre network in singlepress nips. It was successfully applied for studyingdensification and dewatering in both normal wet pressing andhigh temperature wet pressing. However, the first model onlyincludes rate dependence in the compression phase of thecompressionexpansion cycle; the expansion phase is treated asbeing rate independent The second model of the stress-strain behaviour of the fibrenetwork treats both compression and expansion as being ratedependent, according to experimental observations. It is basedon the idea that the wet fibre web may be conceived as alayered network of restricted swelling gels. A swollen fibre isa restricted gel, the inner swelling pressure in a swollenfibre wall being balanced by the stresses in the fibre wallstructure. The observed rate dependence of wet webs in bothcompression and expansion phases was attributed to the flow ofwater out of and into the fibre walls. The second model gavepredictions that are in good agreement with results fromuniaxial experiments using pressure pulses of arbitrary shapefor both a single pulse and a sequence of pulses. It maytherefore be used as a general model for the rheologicalbehaviour of the wet fibre network in wet pressing, providedthe model parameters are estimated from experimental data withsmall experimental error. KEYWORDS:Paper, modelling, dewatering, forming, wetpressing, fibre network stress, rheology, hysteresis,intra-fibre water, compressibility, structural stress,stress-strain, restricted gels, swelling. / <p>QC 20161026</p> paper modelling dewatering forming wet pressing fibre network stress rheology hysteresis intra-fibre water compressibility structural stress stress-strain restricted gels swelling
219	Biopolímero de fibrina como scaffold para células–tronco e secretomas na formação de novo osso Capuano Neto, Fausto. January 2019 (has links) Orientador: Rui Seabra Ferreira Junior / Resumo: Atualmente são muitos casos de pacientes que perdem estrutura óssea em acidentes ou reabsorção patológica. A bioengenharia óssea é um tratamento promissor que visa reconstruir estas estruturas sem a morbidade do enxerto autógeno. O tecido ósseo é um conjuntivo especializado com a função principal de proteção e sustentação dos tecidos moles, mas também é responsável pela produção de tipos celulares e homeostase de minerais. Sua reparação é complexa com diferentes tipos celulares e agentes quimiotáticos que funcionam de forma orquestrada até a reparação. As terapias celulares vêm sendo estudadas para promover a reparação de defeitos que o organismo por si não consegue resolver. Células menos especializadas como as células-tronco embrionárias (ESCs) possuem grande potencial terapêutico, mas são complicadas eticamente. Já as células-tronco mesenquimais (MSC) podem ser autólogas, o que minimiza o risco de imunogenicidade mas necessitam área doadora do paciente. Atualmente ainda não há consenso quanto ao uso de células tronco na terapia regenerativa pois há grandes variáveis como a melhor forma de aplicação, a quantidade correta e o melhor tipo celular para a regeneração óssea. As células produzem mediadores químicos no local enxertado, que segundo pesquisas recentes é o principal mecanismo de reparação tecidual. Estes mediadores são depositados em abundância no meio de cultura durante a cultura celular e usados na bioengenharia com a ajuda de scaffolds. Os biopolímeros de fibrina ... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Chapter I present a review about bone repair and its biological events, bioengineering, cells, fibrin biopolymer as scaffold and the secretoma derived from cell culture. Many patients nowadays lose bone structure in accidents or pathological reabsorption. Bone bioengineering is a promising treatment that aims to reconstruct these structures without autogenous graft morbidity. Bone tissue is a specialized connective tissue specialized in protecting and supporting soft tissues, but it is also responsible for the production of cell types and mineral homeostasis. The bone healing is a complex process where different cell types and chemotactic agents work in an orchestrated way. The cell therapies can promote the repair of defects that the body cannot solve. Less specialized cells like embryonic stem cells (ESCs) have great therapeutic potential, but are ethically complicated. In contrast, mesenchymal stem cells (MSCs) may be autologous, which minimizes the risk of immunogenicity but requires a patient's donor area. Currently there is still no consensus regarding the use of stem cells in regenerative therapy, studies uses different methods, cells and biomaterials for bone regeneration. Recent researches advocate that paracrine secretions by cells are main mechanism of tissue repair. These mediators are deposited in abundance in the culture medium during cell culture. Fibrin biopolymers (BF) are natural biomaterials to the body and can function as drug delivery of growth factors, c... (Complete abstract click electronic access below) / Doutor Secretoma Géis de fibrina Células tronco embrionárias células-tronco mesenquimais bioengenharia óssea Secretome Fibrin Gels Embryonic Stem Cell Células mesenquimais estromais. bone tissue engeneering
220	Vývoj vysokohodnotných betonů s využitím druhotných surovin / The development of high performance concrete with secondary raw materials Osuská, Lucia January 2016 (has links) The thesis is focused on the possibility of using secondary energy resources as an additive to concrete to improve some of its resulting properties. The theoretical part is devoted to the problems of shrinkage and prominence hydration process during hydration of the concrete. This section also contains the results of research work from domestic and foreign sources of high temperature fly ash and fluidized bed combustion fly ash use and their using in concrete. The practical part verifies the possibility of using these materials and their combination as an additive to concrete with impact on the physical and mechanical properties.

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