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THE ROLE OF ENERGY DISSIPATION, SUPERELASTICITY, AND SHAPE MEMORY EFFECTS IN ARCHITECTED MATERIALS FOR ENGINEERING APPLICATIONSKristiaan Hector (13892400) 13 October 2022 (has links)
<p>The main goal of this thesis research is to expand the range of unique properties of phase transforming cellular materials (PXCMs), a new class of architected materials, and to extend their applicability both in the engineering disciplines and in the medical field. A novel aspect of PXCMs is their unique energy dissipation during loading via a snapping mechanism associated with a geometric transition between one stable configuration to another stable configuration at the unit cell level. Phase transformation is analogous to displacive transformations, such as martensitic transformations in shape memory alloys, with no change in configurational entropy. To accomplish this goal, three problem areas are addressed with the first exploring the effects of length scale as added structural hierarchy on material properties and energy dissipation, the second providing an analysis of the durability of architected materials via a novel additive manufacturing method, and the third, an extension into the medical field. Two examples are provided that demonstrate the effects of length scale as added structural hierarchy on material properties, and a machine learning approach for the feasible design of materials with additional levels of structural hierarchy is presented. A simple design approach coupled with a novel additive manufacturing method is discussed for the design of architected materials with high durability. Lastly, a concept for de-clogging bile stents via a temperature driven, shape-memory mechanism inspired by peristaltic locomotion in the human esophagus is presented.</p>
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Endoprothèses vasculaires biorésorbables dans la revascularisation coronarienne : traitement de la coronaropathie extensive et caractéristiques angiographiques de la resténoseEl Yamani, Mohammed El Mehdi 12 1900 (has links)
Il y a plus de 40 ans, la cardiologie interventionnelle a vu le jour et n’a cessé de révolutionner la prise en charge de l’athérosclérose coronarienne. Les endoprothèses vasculaires biorésorbables (BVS) avaient été conçues pour pallier les risques liés à la présence permanente de tuteurs métalliques dans les artères. En principe, ils fournissent de manière transitoire un soutien mécanique pour le scellement des dissections et la prévention du vasospasme et du remodelage constrictif en plus d’une élution médicamenteuse avant de se résorber et restaurer la vasomotricité coronarienne. L’enthousiasme autour des endoprothèses biorésorbables ABSORB™ était mitigé par un risque soutenu de thrombose du tuteur. Ce mémoire traitera en premier lieu des bases moléculaires de l’athérosclérose. Il abordera ensuite la prise en charge de la coronaropathie athérosclérotique ainsi que l’histoire de la cardiologie interventionnelle et ses différentes révolutions. Ensuite, deux études cliniques ont été conduites dans le cadre de ce travail et seront présentées. La première étude évalue le rôle du BVS dans la revascularisation de la coronaropathie extensive (multivaisseaux ou diffuse) et a montré que, dans un contexte aussi peu favorable au déploiement d’un tuteur coronarien, ABSORB™ a présenté des résultats cliniques acceptables à très long terme comparativement aux tuteurs métalliques de deuxième génération. La deuxième étude s’intéresse quant à elle aux caractéristiques angiographiques de resténose des BVS. Elle a démontré qu’à long terme, la resténose des BVS devient de plus en plus diffuse, et était associée à des issues cliniques moins favorables. Le dernier chapitre de ce mémoire se constitue d’une ouverture conclusive présentant les différentes endoprothèses biorésorbables actuellement à l’étude ou en cours de développement en soulignant leurs principales différences avec ABSORB™. / More than 40 years ago, interventional cardiology was born and has continued to revolutionize the management of coronary atherosclerosis. Bioresorbable Vascular Scaffolds (BVS) were designed to alleviate the risks associated with the permanent presence of metal stents in the arteries. In theory, they provide a transient mechanical support for sealing dissections and preventing vasospasm and constrictive remodeling in addition to a drug-eluting function before complete bioresorption and restoration of coronary vasomotion. Enthusiasm around the ABSORB™ bioresorbable scaffold was mitigated by a sustained risk of scaffold thrombosis. This thesis will first review the molecular basis of atherosclerosis. It will then discuss the management of atherosclerotic coronary artery disease, the history of interventional cardiology and its multiple revolutions. Then, two clinical studies that were conducted as part of this work will be presented. The first study that evaluates the role of BVS in the revascularization of extensive coronary artery disease (multivessel or diffuse) showed that, in such an unfavorable context for the deployment of a coronary stent, ABSORB™ has shown acceptable clinical results in the very long term compared to second generation drug-eluting stents. The second study focuses on the angiographic patterns of BVS restenosis. It showed that in the long term, the pattern of restenosis tended to be more diffuse than focal and that restenosis was associated with less favorable clinical outcomes. The final chapter of this thesis presents the different bioresorbable scaffolds currently under study or under development while highlighting their main differences with ABSORB™.
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