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[1]
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Structural design optimization through finite element analysis of additive manufactured bioresorbable polymeric stents
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Materials Today Chemistry,
2024 |
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[2]
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Revolutionizing Cardiovascular Frontiers: A Dive Into Cutting-Edge Innovations in Coronary Stent Technology
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Cardiology in Review,
2024 |
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[3]
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A Unified Empirical Equation for Determining the Mechanical Properties of Porous NiTi Alloy: From Nanoporosity to Microporosity
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Crystals,
2023 |
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[4]
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Comparative study of stent performance under combined loading
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2023 |
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[5]
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Modèle rapide de plasticité cristalline dans les polycristaux pour la fatigue à grand nombre de cycles
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2023 |
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[6]
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A novel biodegradable high nitrogen iron alloy with simultaneous enhancement of corrosion rate and local corrosion resistance
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Journal of Materials …,
2023 |
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[7]
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Is There an Advantage of Ultrathin-Strut Drug-Eluting Stents over Second-and Third-Generation Drug-Eluting Stents?
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Journal of Personalized Medicine,
2023 |
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[8]
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Dual strengthened corrosion control of biodegradable coating on magnesium alloy for vascular stent application
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Progress in Organic …,
2023 |
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[9]
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DEPLOYMENT BEHAVIOR OF STENT IN TAPERED VESSELS WITH MULTIPLE STENOSES: EFFECT OF DIFFERENT IMPLANTATION PLANNING …
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Journal of Mechanics in …,
2023 |
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[10]
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磁兼容 Au-25Pt 合金的组织结构及综合性能.
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Precious …,
2022 |
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[11]
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3D Printing of Polymeric Bioresorbable Stents: A Strategy to Improve Both Cellular Compatibility and Mechanical Properties
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Polymers,
2022 |
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[12]
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Evolutionary perspective of drug eluting stents: from thick polymer to polymer free approach
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Journal of …,
2022 |
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[13]
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Coronary Stent Fracture Causing Myocardial Infarction: Case Report and Review of Literature
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Reviews in Cardiovascular …,
2022 |
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[14]
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Balloon expandable coronary stent materials: a systematic review focused on clinical success
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In vitro models,
2022 |
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[15]
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3D Printing of Polymeric Bioresorbable Stents: A Strategy to Improve both Cellular Compatibility and Mechanical Properties. Polymers 2022, 14, 1099
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2022 |
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[16]
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A review on design characteristics and fabrication methods of metallic cardiovascular stents
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Materials Today …,
2022 |
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[17]
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Alternativni materijali za 3D tisak
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2022 |
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[18]
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Au-12Ge 钎料箔材的工艺集成制备与组织演化研究.
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Precious …,
2022 |
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[19]
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Mechanical properties, in vitro and in vivo biocompatibility analysis of pure iron porous implant produced by metal injection molding: A new eco-friendly feedstock from …
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Materials Science and …,
2021 |
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[20]
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Microstructural and mechanical characterization of thin-walled tube manufactured with selective laser melting for stent application
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2021 |
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[21]
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Preliminary study on modelling, fabrication by photo-chemical etching and in vivo testing of biodegradable magnesium AZ31 stents
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2021 |
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[22]
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Stress distribution on a cobalt-chromium stent placed into an artery with and without atherosclerotic plaque
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2020 |
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[23]
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Design, Fabrication, and Testing of Photo-chemically Etched Biodegradable Stents
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2020 |
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[24]
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Modelling, Fabrication by Photo-Chemical Etching and in Vivo Study of Magnesium AZ31 Stents
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2020 |
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[25]
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Structural optimization and finite element analysis of poly‐l‐lactide acid coronary stent with improved radial strength and acute recoil rate
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2020 |
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[26]
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Damar İçi Stentlerde Malzeme Seçiminin ve Tasarımının Restenoz ve Diğer Stent Kaynaklı Problemlere Etkileri, Stentlerin Ekonomideki Yeri (Bir Genel Derleme)
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2020 |
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[27]
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Effect of Surface-Modification on In Vitro Corrosion of Biodegradable Magnesium-Based Helical Stent Fabricated by Photo-chemical Etching
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2020 |
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[28]
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A Computational Study of Mechanical Performance of Bioresorbable Polymeric
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2020 |
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[29]
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Fabricação de órteses endovasculares pelo processo de micromoldagem de pós metálicos por injeção (μMIM)
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2020 |
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[30]
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Дослідження властивостей металевих виробів складної форми виготовлених методом селективного лазерного плавлення
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2020 |
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[31]
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3D printed composite materials for craniofacial implants: current concepts, challenges and future directions
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2020 |
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[32]
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ЧИСЛЕННАЯ ОЦЕНКА УСТАЛОСТНОЙ ПРОЧНОСТИ КАРКАСА ТРАНСКАТЕТЕРНОГО БИОПРОТЕЗА МИТРАЛЬНОГО КЛАПАНА НА ОСНОВЕ …
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2019 |
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[33]
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Eletrodeposição de ligas bioabsorvíveis do sistema Fe-Mn
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2019 |
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[34]
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NUMERICAL ASSESSMENT OF FATIGUE STRENGTH OF TRANSCATHETER MITRAL BIOPROSTHETIC STENT BASED ON THE TITANIUM NICKELIDE …
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Российский журнал …,
2019 |
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[35]
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Mechanical properties and performances of contemporary drug-eluting stent: focus on the metallic backbone
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2019 |
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[36]
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Analysis of the whole implementation process and optimization of a Nitinol superelastic stent
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2019 |
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[37]
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Multiscale Analysis of Bulk Metallic Glasses for Cardiovascular Applications
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2019 |
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[38]
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Fatigue behavior of stent in tapered arteries: The role of arterial tapering and stent material
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2019 |
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[39]
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Interventional Cardiology and Cardiac Catheterisation: The Essential Guide
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2019 |
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[40]
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Advances in stent technology
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2019 |
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[41]
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Ανάλυση αποτελεσματικότητας του κόστους και του κοινωνικού οφέλους των βιοαποδομήσιμων ικριωμάτων μαγνησίου (RMS) σε υποομάδες ασθενών με στεφανιαία …
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2018 |
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[42]
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Bioresorbable Scaffold Stability and Mechanical Properties
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Textbook of Catheter-Based Cardiovascular Interventions,
2018 |
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[43]
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Influence of the Realistic Artery Geometry Parameters on a Coronary Stent Fatigue Life
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International Journal of Computational Methods,
2018 |
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[44]
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Coronary stent fracture: clinical evidence vs. the testing paradigm
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Cardiovascular Engineering and Technology,
2018 |
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[45]
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Inclusion Effects on the Lifetime Performance of Superelastic Nitinol Wires
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Dissertation, Case Western Reserve University,
2018 |
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[46]
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A Computational Study of Mechanical Performance of Bioresorbable Polymeric Stents with Design Variations
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2018 |
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[47]
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Υπολογιστική παραμετρική μοντελοποίση έκπτυξης ενδοπρόθετης σε πραγματικές αρτηρίες
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2018 |
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[48]
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Cost Effectiveness and Social Benefit of Resorbable Magnesium Scaffolds in Coronary Artery Disease Patient Subgroups
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2018 |
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[49]
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Unlocking scaffold mechanical properties
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2017 |
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[50]
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Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models
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Scientific Reports,
2017 |
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[51]
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Fatigue Strength of a Novel Heart Valve Bioprosthesis
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2017 |
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[52]
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УСТАЛОСТНАЯ ПРОЧНОСТЬ НОВОГО БИОПРОТЕЗА КЛАПАНА СЕРДЦА
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2017 |
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[53]
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FINITE ELEMENT ANALYSIS OF SHAPE MEMORY ALLOY NiTi STENT IN CORONARY ARTERY
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2017 |
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[54]
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Preclinical assessment of bioresorbable scaffolds and regulatory implication
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2017 |
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[55]
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A review on fracture prevention of stent in femoropopliteal artery
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IOP Conference Series: Materials Science and Engineering,
2017 |
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[56]
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Functional Nanoarchitectures For Enhanced Drug Eluting Stents
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Scientific reports,
2017 |
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[57]
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Low friction and high strength of 316L stainless steel tubing for biomedical applications
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Materials Science and Engineering: C,
2017 |
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[58]
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Propiedades biológicas in vitro de polímeros epoxídicos modificados con diluyente reactivo
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2016 |
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[59]
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Micromechanical modeling for the probabilistic failure prediction of stents in high-cycle fatigue
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International Journal of Fatigue,
2016 |
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[60]
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ASSESSMENT OF CORONARY STENT DEPLOYMENT IN TAPERED ARTERIES: IMPACT OF ARTERIAL TAPERING
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Journal of Mechanics in Medicine and Biology,
2016 |
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[61]
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Anatomic assessment of the left main bifurcation and dynamic bifurcation angles using computed tomography angiography
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2016 |
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[62]
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Epoxy/aliphatic amine networks with perspectives for cardiovascular applications. In vitro biological properties
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Matéria (Rio de Janeiro),
2016 |
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[63]
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Redes epóxi/amina alifáticas com perspectivas para aplicações cardiovasculares. Propriedades biológicas in vitro
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2016 |
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[64]
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Bioresorbable stents: Current and upcoming bioresorbable technologies
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International Journal of Cardiology,
2016 |
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[65]
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Photochemical machining of a novel cardiovascular stent
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Annals of the American Association of Geographers,
2016 |
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[66]
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The metamorphosis of vascular stents: passive structures to smart devices
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RSC advances,
2016 |
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[67]
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A computational approach for the lifetime prediction of cardiovascular balloon-expandable stents
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International Journal of Fatigue,
2015 |
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[68]
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Fatigue of Metallic Stents: From Clinical Evidence to Computational Analysis
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Annals of biomedical engineering,
2015 |
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[69]
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Ti-based functional nanoarchitectures for enhanced drug eluting stents
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2015 |
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[70]
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Biocompatibility Assessment of Biosorbable Polymer Coated Nitinol Alloys
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2014 |
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[71]
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Micromechanics of fatigue with application to stents
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2014 |
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[72]
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Analysis of User Acceptability Factors for Optimum Design of Coronary Stent
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ICBETA 2014,
2014 |
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[73]
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Medical Devices: Coronary Stents
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2014 |
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