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Obtenção de cerâmicas porosas de alumina-zircônia pelo método da réplica recobertas com fosfato de cálcio / Obtaining porous alumina-zirconia ceramics by the calcium phosphate-coated replica methodAndré Diniz Rosa da Silva 10 August 2017 (has links)
As cerâmicas porosas empregadas na substituição óssea, são utilizadas por apresentarem características como biocompatibilidade, ter estrutura tridimensional e apresentar alta porosidade. Nesse sentido, o objetivo desse trabalho foi obter e caracterizar cerâmicas porosas de Al2O3 e Al2O3 contendo 5% em volume de inclusões de ZrO2, produzidas pelo método da réplica. Essas cerâmicas porosas tiveram sua superfície tratada quimicamente com ácido fosfórico e foram recobertos, com fosfato de cálcio usando o método biomimético, em solução de SBF 5X (Simulated Body Fluid) por um período de incubação de 14 dias. Após o recobrimento, algumas cerâmicas porosas foram tratadas quimicamente para incorporação do Sr2+. Em seguida foram caracterizadas morfologicamente e estruturalmente usando ensaios de compressão axial, porosidade aparente, microscopia eletrônica de varredura (MEV), microtomografia de Raio X (µ-CT), difratometria de Raio X (DRX), Espectroscopia de Infravermelho Próximo (NIR), emissão óptica com plasma indutivamente acoplado (ICP-OES), Energia Dispersiva de Raio-X (EDS) e por Ensaios biológicos utilizando cultura de células para análise de viabilidade celular. As cerâmicas porosas de alumina e alumina-zircônia apresentaram, respectivamente, porosidade aparente de 80,93 % e 78,82 %, resistência à compressão axial, 2,93 MPa e 6,59 MPa, além de uma ampla faixa de tamanho de poros de, desejáveis para o favorecimento de interesses biológicos destinados à regeneração e formação de tecido ósseo. O recobrimento biomimético usando SBF 5X produziu a formação das fases α-TCP, β-TCP, TTCP e Hidroxiapatita, usando período de incubação de 14 dias. A incorporação de Sr2+ na estrutura dos fosfatos mostrou-se mais eficientes nos corpos porosos de alumina-zircônia. Os ensaios in vitro mostraram a biocompatibilidade das cerâmicas porosas estudadas, demonstrando a possibilidade de sua utilização como material para substituição ou preenchimento ósseo. / The porous ceramics used in bone substitution are used because they present characteristics as biocompatibility, have a three - dimensional structure and have high porosity. In this sense, the objective of this work was to obtain and characterize porous ceramics of Al2O3 and Al2O3 containing 5% by volume of ZrO2 inclusions, produced by the replica method. These porous ceramics were chemically treated with phosphoric acid and were coated with calcium phosphate using the biomimetic method in 5X SBF solution (Simulated Body Fluid) for a 14 day incubation period. After coating, some porous ceramics were chemically treated for Sr2+ incorporation. They were then characterized morphologically and structurally using axial compression, apparent porosity, scanning electron microscopy (SEM), microtomography (µ-CT), X-ray diffractometry (XRD), Near Infrared (NIR) Coupled (ICP-OES), X-ray Dispersive Energy (EDS) and Biological Assays using cell culture for cell viability analysis. The porous ceramics of alumina and alumina-zirconia showed, respectively, 80.93% and 78.82% apparent porosity, axial compression strength, 2.93 MPa and 6.59 MPa, as well as a wide range of pore size, desirable for the promotion of biological interests destined to the regeneration and formation of bone tissue. Biomimetic coated using SBF 5X produced the formation of α-TCP, β-TCP, TTCP and Hydroxyapatite phases using a 14-day incubation period. The incorporation of Sr2+ in the phosphate structure proved to be more efficient in porous alumina-zirconia bodies. The in vitro tests showed the biocompatibility of the porous ceramics studied, demonstrating the possibility of their use as material for bone replacement or filling.
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Composites in the alumina-zirconia system : An engineering approach for an effective tailoring of microstructural features and performances / Composites dans le système alumine-zircone : Une approche d’ingénierie des poudres permettant de façonner les caractéristiques microstructurales et compositionnellesFornabaio, Marta 27 March 2014 (has links)
L’objectif de cette thèse est le développement de composites dans le système alumine-zircone par une approche d’ingénierie des poudres permettant de façonner les caractéristiques microstructurales et compositionnelles, et, par conséquent, les propriétés des matériaux finaux. Les poudres composites ont été elaborée à travers la modification de la surface des poudres commerciales par un précurseur inorganique de les phases secondaires . Cette approche innovante assure un degré élevé du contrôle de la taille et de la distribution des grains de seconde phase sur la surface du matériau parent. Les poudres composites à base d’alumine contenant 10 vol% de zircone non-stabilisée et des poudres composites à base de zircone triphasique contenant 8 vol% d’alumine et 8 vol% de phase aluminate, ont été développées. Leur propriétés physiques, chimiques et mécaniques a été caractérisé. Dans le cas premier, les materials porous ont été développés à travers le technique gel-casting avec sphères de PE. Les mécanismes de ténacité de la zircone ont été étudiés, révélant aucun influence sur les propriété mécaniques. Les composites poreux présentent des valeurs de résistance à la rupture plus élevées, en comparant à des alumines pures, mais cet amélioration peut être raisonnablement dû à leur microstructure plus fine, celle-ci étant caractérisée par des grains et des pores plus petits. Dans le deuxième cas, a partir de la Ce-TZP, connue pour sa ténacité et sa stabilité importantes, un travail d’optimisation de la microstructure a été réalisé afin d’obtenir une résistance à la rupture maximale. Les matériaux présentés dans cette étude ont été développés afin de répondre au triple objectif de ténacité, résistance et stabilité. Deux composites très prometteurs, avec des résistances à la rupture élevées (environ 900 MPa) et ténacités élevées (environ 10Mpa√m), ont été réalisés. De plus, les composites étudiés ont montré de hautes capacités de transformation et pas de faible température de dégradation en atmosphère humide, dans les temps des applications médicales. Il a été démontré que les propriétés mécanique sont vivement affectées par le degré de stabilisation de la zircone. L’étude de la relation entre les propriétés finales et l’architecture de la composition/microstructure, au but d’obtenir les propriétés désirées, se révèle nécessaire. / The aim of this PhD study is the development of composites in the alumina-zirconia system through a powder engineering approach which allows tailoring the compositional and microstructural features, and, as a consequence, the properties of the final materials. The experimental activities refer to two different projects. The first, named MITOR project, was devoted to the elaboration and mechanical characterization of macro-porous Alumina-Zirconia composites. It dealt with the development of a new method for the elaboration of composite cellular ceramics and with the investigation of the role of zirconia and its toughening mechanisms in porous materials, thus filling a gap in the scientific literature. The latter, a European Project named Longlife, was dedicated to the preparation and characterization of zirconia (stabilized with ceria)-based composites for dental and spine implants. The major aim was to overcome the drawbacks proper of yttria-zirconia-based materials, concerning their stability in moisture atmosphere as well as their low toughness. Ceria-zirconia-based composites should benefit from phase transformation toughening still keeping high strength. In addition, they should not suffering of surface degradation in presence of water. So, materials characterized by high strength, high toughness with a perfect reliability and a lifetime longer than 60 years were investigated. Alumina-based composite powders containing 10 vol% of un-stabilized zirconia as well as tri-phasic zirconia-based composite powders containing 8 vol% of alumina and 8 vol% of an aluminate phase(Srontiuma nd Magnesium hexaxaluminate), were developed and characterized in terms of phase evolution and thermal behaviour. In addition, the adopted elaboration route allowed tailoring the ceria amount inside the zirconia grains: four different zirconia stabilization degree were thus investigated. Two very promising composites with high fracture strength, of about 900 MPa, and high crack resistance were found. Furthermore, the investigated composites showed high transformability and no low temperature degradation in moisture atmosphere in the time-scale of medical applications. It was shown that the deep knowledge of all the involved mechanisms (such as raw powders dispersion, pH suspension, powder thermal treatments) is crucial for achieving a full control of the powders features and, consequelntly, of the final microstructures.
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Carbon nanotubes developed on ceramic constituents through chemical vapour depositionLiu, JingJing January 2012 (has links)
Carbon nanotubes (CNTs) were successfully grown on the surface of carbon fibre reinforcements in carbon fibre architecture through in-situ catalytic chemical vapour deposition (CCVD). Success was also implemented on powders of oxides and non-oxides, including Y-TZP powder, ball milled alumina powder, alumina grits, silicon carbide powder. Preliminary results have been achieved to demonstrate the feasibility of making ceramic composites consisting of CNTs reinforcements.
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In vitro evaluation of cell-material interactions on bioinert ceramics with novel surface modifications for enhanced osseointegration / Evaluation in vitro des intéractions cellules-matériaux sur des céramiques bioinertes avec des modifications de la surface nouvelles pour une osseointegration améliorréeStanciuc, Ana-Maria 23 June 2017 (has links)
Cette thèse porte sur l'évaluation de la réponse cellulaire in vitro vis-à-vis de différentes stratégies de modification de surface pour améliorer la capacité d’ostéointégration de céramiques bioinertes pour implants orthopédiques et dentaires. Premièrement des surfaces l'alumine-zircone avec différentes micro-rugosités obtenues par moulage par injection ont été étudiées. Le comportement d'ostéoblastes primaires humains (obtenus à partir de têtes de fémurs soumis à arthroplastie) a été étudié sur les surfaces telles quelles ou modifiées par traitement avec acide hydrofluorique. La micro-rugosité a eu seulement un effet mineur sur la réponse ostéoblastique tandis que la combinaison de micro- et nano-rugosité a eu un effet synergique sur la maturation ostéoblastique. Cette stratégie de modification de surface ouvre la voie vers des cupules acétabulaires céramiques monoblocs directement ostéo-intégrées. Deuxièmement, le robocasting (une technique d’impression 3D) a été exploré pour la production de structures macroporeuses en alumine-zircone avec une haute reproductibilité et contrôle architectural. Les structures imprimées ont présentées une topographie aux multiples niveaux grâce au design et les conditions de frittage. Les ostéoblastes ont pu s'attacher sur les structures 3D mais la préservation des cellules à l’intérieur des scaffolds sur le long terme reste à améliorer. Des techniques de sélection rapide de modifications de surface ont fait l'objet de la dernière partie de cette thèse. Deux différentes stratégies ont été utilisées sur la zircone: laser femtoseconde pour la production de multiples motifs sur un échantillon unique et échantillons avec un gradient de rugosité via le contrôle du temps d’attaque chimique. La morphologie des cellules souches humaines a permis d'avoir un indicateur précoce de la lignée de différentiation cellulaire. En conclusion, les différentes techniques de modification de surface de zircone et alumine-zircone utilisées à travers la thèse peuvent moduler l’interaction cellule-matériau en stimulant la différentiation ostéoblastique de cellules souches et la maturation des ostéoblastes. / The focus of this PhD thesis is the in vitro evaluation of cell-material interactions on bioinert ceramics with novel surface modifications for enhanced osseointegration of orthopaedic and dental implants. Firstly, alumina-zirconia surfaces with different micro-roughnesses obtained by injection moulding were studied. The behaviour of human primary osteoblasts (hObs) obtained from patients undergoing total hip replacements was studied on the different micro-rough ZTA surfaces and on combined micro-/nano-rough surfaces modified by hydrofluoric acid treatment. Micro-roughness alone had minor effects on hOb response while the combination micro-/nano-roughness induced a synergic effect on hOb maturation. This latter surface modification technique opens the way to the fabrication of ceramic acetabular cups with direct implantation capabilities. Secondly, robocasting (a 3D printing technique) was explored for the fabrication of a alumina-zirconia macroporous structures with high reproducibility and control of the architecture. Roughness at different scales was observed for the 3D structures due to the scaffold design and to the low temperature sintering conditions. Osteoblasts were able to attach on the 3D structures but cell retention at long term needs further optimization. Rapid screening of cell-material interactions was the subject of the last part of the thesis. Two different strategies were tested on zirconia: femtosecond laser to produce multiple patterns on a single sample and samples with a roughness gradient by the control of chemical etching time. Stem cell morphology was used as an early marker of cell differentiation lineage. In conclusion, the different surface modification techniques of zirconia and alumina-zirconia surfaces used in the thesis allow the modulation of cell-material interactions by stimulating stem cells osteogenesis and osteoblast maturation.
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Densification Mechanisms for Spark Plasma Sintering in Alumina and Alumina Based SystemsChakravarty, Dibyendu January 2013 (has links) (PDF)
The densification mechanisms of polycrystalline α-alumina by spark plasma sintering are highly contradictory, with different research groups suggesting diffusion to dislocation controlled mechanisms to be rate controlling. The specific objective of this work was to investigate densification mechanisms of α-alumina during the intermediate and final stages of sintering by SPS, analyze the microstructural development and establish sintering trajectories. In addition, zirconia and yttria were added in different weight percentages to study the effect of solute concentration on the densification kinetics of spark plasma sintered alumina. The present work adopts a different approach from the classical method adopted previously to analyze the sintering kinetics and densification mechanisms of alumina in SPS, although existing models for hot pressing were adopted for the basic analysis.
The densification behavior was investigated in the temperature range 1223-1573 K under applied stresses of 25, 50 and 100 MPa and grain sizes between 100 and 250 nm. The SEM micrographs reveal equiaxed grains with no abnormal grain growth in the dense samples. The ‘master sintering curve’ shows grain size to be primarily dependent on density, irrespective of the applied stresses or temperature. The stress exponent of 1 along with an inverse grain size exponent of 3 and activation energy of 320-550 kJ mol-1 suggests Al3+ grain boundary diffusion as the rate controlling densification mechanism in alumina.
The densification rates are marginally slower in compositions with 0.1% Y2O3 and ZrO2 content possibly due to the smaller grain sizes used in this study which leads to faster rates compared to earlier reports. However, higher Y2O3 and ZrO2 content led to decrease in densification rate by more than an order of magnitude possibly due to presence of a second phase which increases the effective path length for diffusion, thereby reducing the densification rates. Presence of Y2O3 and ZrO2 in the compositions with 0.1% Y2O3 and ZrO2 were confirmed by TEM studies. The Y3Al5O12 (YAG) phase developed between 1223 and 1273 K and suppressed densification and grain growth in alumina. In spite of higher temperatures required for alumina-YAG and alumina-zirconia composites to attain density ~99%, the alumina grain size in the composites was smaller than that in pure alumina due to the Zener drag effect. The stress exponents obtained for Y2O3 and ZrO2 composites at both the concentrations yield a value of n~ 2, which indicates a change in densification mechanism from pure alumina. The higher stress dependence of these composites could be due to presence of solute and second phase formation, both of which retard densification rates. The inverse grain size exponents obtained are between 1 and 2; both stress exponent and grain size exponent values suggest an interface reaction controlled diffusion mechanism occurring in these composites, independent of the Y2O3 and ZrO2 content. Higher activation energies are obtained with the Y2O3 and ZrO2 composites of higher content, respectively, due to presence of second phase particles at grain boundaries.
The presence of solutes at grain boundaries hinders grain boundary diffusion of alumina, leading to interface reaction controlled process; this is confirmed by superimposing standard aluminum grain boundary and lattice diffusion data on to stress-densification rate data obtained in this work. A comparison of stress exponents using current experimental data adopting the present and the classical approaches show a wide difference in their values indicating a change in the rate controlling diffusion path, necessitating a review of the assumptions made on the basic equations used in previous SPS studies.
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