| Nome |
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Idealized models of arterial bifurcation to investigate diseased coronary hemodynamics, file e384c42f-8c7c-d4b2-e053-9f05fe0a1d67
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208
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Hemodynamic risk in coronary bifurcations: a computational exploration, file e384c42f-925b-d4b2-e053-9f05fe0a1d67
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116
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On the impact of geometry on near-wall and intravascular flow features in idealized, population-based coronary bifurcations, file e384c42f-9259-d4b2-e053-9f05fe0a1d67
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98
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Computational fluid dynamics of stented coronary bifurcations studied with a hybrid discretization method, file e384c431-017f-d4b2-e053-9f05fe0a1d67
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88
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Does the shape of inflow velocity profiles affect hemodynamics in computational coronary artery models?, file e384c431-68f0-d4b2-e053-9f05fe0a1d67
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83
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On the necessity of modelling fluid–structure interaction for stented coronary arteries, file e384c430-f0e7-d4b2-e053-9f05fe0a1d67
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78
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On the association between helical flow and plaque progression in coronary arteries, file e384c431-37dd-d4b2-e053-9f05fe0a1d67
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77
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Patient-Specific Modeling of Stented Coronary Arteries Reconstructed from Optical Coherence Tomography: Towards a Widespread Clinical Use of Fluid Dynamics Analyses, file e384c430-f019-d4b2-e053-9f05fe0a1d67
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64
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ON THE ASSOCIATION BETWEEN HELICAL BLOOD FLOW AND ATHEROSCLEROTIC PLAQUE GROWTH IN CORONARY ARTERIES, file e384c430-e575-d4b2-e053-9f05fe0a1d67
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35
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A framework for computational fluid dynamic analyses of patient-specific stented coronary arteries from optical coherence tomography images, file e384c430-f020-d4b2-e053-9f05fe0a1d67
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35
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Wall shear stress topological skeleton analysis in cardiovascular flows: Methods and applications, file e384c433-b4f0-d4b2-e053-9f05fe0a1d67
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34
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In silico biomechanical design of the metal frame of transcatheter aortic valves: multi-objective shape and cross-sectional size optimization, file e384c433-b41a-d4b2-e053-9f05fe0a1d67
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29
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The Atheroprotective Nature of Helical Flow in Coronary Arteries, file e384c430-6a31-d4b2-e053-9f05fe0a1d67
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28
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Association between helical blood flow and atherosclerotic plaque progression in coronary arteries: an animal-specific study., file e384c431-0bef-d4b2-e053-9f05fe0a1d67
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25
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Computing patient-specific hemodynamics in stented femoral artery models obtained from computed tomography using a validated 3D reconstruction method, file e384c431-c5c4-d4b2-e053-9f05fe0a1d67
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25
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Simultaneous kissing stents to treat unprotected left main stem coronary artery bifurcation disease; stent expansion, vessel injury, hemodynamics, tissue healing, restenosis, and repeat revascularization, file e384c431-6b0f-d4b2-e053-9f05fe0a1d67
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21
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Design rules for producing cardiovascular stents by selective laser melting: Geometrical constraints and opportunities, file e384c431-c5c9-d4b2-e053-9f05fe0a1d67
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21
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Comparison of Swine and Human Computational Hemodynamics Models for the Study of Coronary Atherosclerosis, file e384c434-52df-d4b2-e053-9f05fe0a1d67
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21
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A patient-specific study investigating the relation between coronary hemodynamics and neo-intimal thickening after bifurcation stenting with a polymeric bioresorbable scaffold, file e384c430-f024-d4b2-e053-9f05fe0a1d67
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20
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Exploring wall shear stress spatiotemporal heterogeneity in coronary arteries combining correlation-based analysis and complex networks with computational hemodynamics, file e384c432-a522-d4b2-e053-9f05fe0a1d67
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20
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Superficial femoral artery stenting: Impact of stent design and overlapping on the local hemodynamics, file 8c3e5a3c-f9e5-4c48-a7b5-de239967c6d9
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17
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Optimal Site for Proximal Optimization Technique in Complex Coronary Bifurcation Stenting: A Computational Fluid Dynamics Study, file e384c432-c9d3-d4b2-e053-9f05fe0a1d67
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17
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Coronary fractional flow reserve measurements of a stenosed side branch: A computational study investigating the influence of the bifurcation angle, file e384c431-0921-d4b2-e053-9f05fe0a1d67
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15
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Reconstruction of stented coronary arteries from optical coherence tomography images: Feasibility, validation, and repeatability of a segmentation method, file e384c431-6b10-d4b2-e053-9f05fe0a1d67
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15
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On the Modeling of Patient-Specific Transcatheter Aortic Valve Replacement: A Fluid–Structure Interaction Approach, file e384c431-900a-d4b2-e053-9f05fe0a1d67
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15
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Fluid-dynamics and biological features of unstable plaques: different shear stress for different plaques, file e384c432-c851-d4b2-e053-9f05fe0a1d67
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14
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EXPLORING THE LINK BETWEEN WALL SHEAR STRESS TOPOLOGICAL SKELETON AND NEAR-WALL MASS TRANSPORT IN CARDIOVASCULAR FLOWS USING A EULERIAN-BASED METHOD, file e384c434-3426-d4b2-e053-9f05fe0a1d67
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14
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Automatic segmentation of optical coherence tomography pullbacks of coronary arteries treated with bioresorbable vascular scaffolds: Application to hemodynamics modeling, file e384c430-f17e-d4b2-e053-9f05fe0a1d67
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13
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Does the inflow velocity profile influence physiologically relevant flow patterns in computational hemodynamic models of left anterior descending coronary artery?, file e384c432-4b77-d4b2-e053-9f05fe0a1d67
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13
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Hemodynamic perturbations due to the presence of stents, file e384c432-98c2-d4b2-e053-9f05fe0a1d67
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13
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EULERIAN-BASED WALL SHEAR STRESS TOPOLOGICAL SKELETON AS A TEMPLATE OF NEAR-WALL MASS TRANSPORT IN ARTERIES, file e384c434-1b54-d4b2-e053-9f05fe0a1d67
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13
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Location-Specific Comparison Between a 3D In-Stent Restenosis Model and Micro-CT and Histology Data from Porcine In Vivo Experiments, file e384c431-8284-d4b2-e053-9f05fe0a1d67
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12
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A Multiscale Model of Atherosclerotic Plaque Development: Toward a Coupling Between an Agent-Based Model and CFD Simulations, file e384c431-9013-d4b2-e053-9f05fe0a1d67
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12
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Does clinical data quality affect fluid-structure interaction simulations of patient-specific stenotic aortic valve models?, file e384c431-c045-d4b2-e053-9f05fe0a1d67
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12
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3D reconstruction of coronary artery bifurcations from coronary angiography and optical coherence tomography: feasibility, validation, and reproducibility, file e384c432-ad34-d4b2-e053-9f05fe0a1d67
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12
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Computational replication of the patient-specific stenting procedure for coronary artery bifurcations: From OCT and CT imaging to structural and hemodynamics analyses, file e384c431-36b4-d4b2-e053-9f05fe0a1d67
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11
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Biomechanical Impact of Wrong Positioning of a Dedicated Stent for Coronary Bifurcations: A Virtual Bench Testing Study, file e384c431-655d-d4b2-e053-9f05fe0a1d67
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11
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A fully coupled computational fluid dynamics – agent-based model of atherosclerotic plaque development: Multiscale modeling framework and parameter sensitivity analysis, file e384c431-c7e4-d4b2-e053-9f05fe0a1d67
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11
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Multidirectional wall shear stress promotes advanced coronary plaque development: comparing five shear stress metrics, file e384c431-dfb0-d4b2-e053-9f05fe0a1d67
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11
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First Report of the One-Point Transradial Two Sheathless Catheters Insertion (OTRANTO) Technique, file e384c432-da6d-d4b2-e053-9f05fe0a1d67
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11
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Differences in rotational positioning and subsequent distal main branch rewiring of the Tryton stent: An optical coherence tomography and computational study, file e384c431-22d6-d4b2-e053-9f05fe0a1d67
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10
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Modeling the stent deployment in coronary arteries and coronary bifurcations, file e384c432-c07b-d4b2-e053-9f05fe0a1d67
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10
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Local fluid dynamics in patients with bifurcated coronary lesions undergoing percutaneous coronary interventions, file e384c433-c30a-d4b2-e053-9f05fe0a1d67
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10
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Three dimensional reconstruction of coronary artery stents from optical coherence tomography: experimental validation and clinical feasibility, file e384c433-db8e-d4b2-e053-9f05fe0a1d67
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10
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3D modelling of drug-coated balloons for the treatment of calcified superficial femoral arteries, file e384c434-067f-d4b2-e053-9f05fe0a1d67
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10
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The impact of helical flow on coronary atherosclerotic plaque development, file e384c432-2237-d4b2-e053-9f05fe0a1d67
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9
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Impact of bioresorbable scaffold design characteristics on local haemodynamic forces: an ex vivo assessment with computational fluid dynamics simulations, file e384c432-e7d1-d4b2-e053-9f05fe0a1d67
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9
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In-Stent Restenosis Progression in Human Superficial Femoral Arteries: Dynamics of Lumen Remodeling and Impact of Local Hemodynamics, file e384c433-e18d-d4b2-e053-9f05fe0a1d67
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9
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Baseline local hemodynamics as predictor of lumen remodeling at 1-year follow-up in stented superficial femoral arteries, file e384c433-fc35-d4b2-e053-9f05fe0a1d67
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9
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WALL SHEAR STRESS TOPOLOGICAL SKELETON VARIABILITY PREDICTS MYOCARDIAL INFARCTION, file e384c434-459a-d4b2-e053-9f05fe0a1d67
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9
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Wall Shear Stress Topological Skeleton Variability Predicts Myocardial Infarction, file e384c434-6b77-d4b2-e053-9f05fe0a1d67
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9
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On the Modeling of Patient-Specific Transcatheter Aortic Valve Replacement: A Fluid–Structure Interaction Approach, file e384c431-8280-d4b2-e053-9f05fe0a1d67
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8
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The Double-Kissing Nano-Crush for Bifurcation lesions: Development, Bioengineering, Fluid dynamics and Initial Clinical Testing, file e384c432-c437-d4b2-e053-9f05fe0a1d67
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8
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Mismatch between morphological and functional assessment of the length of coronary artery disease, file e384c433-b4ef-d4b2-e053-9f05fe0a1d67
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8
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Early Atherosclerotic Changes in Coronary Arteries are Associated with Endothelium Shear Stress Contraction/Expansion Variability, file e384c434-1146-d4b2-e053-9f05fe0a1d67
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8
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Wall shear stress topological skeleton variability predicts plaque growth in human coronary arteries, file 5b33f249-2631-42d4-a911-5b601d71374b
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7
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WALL SHEAR STRESS TOPOLOGICAL SKELETON VARIABILITY PREDICTS ATHEROSCLEROTIC PLAQUE GROWTH IN HUMAN CORONARY ARTERIES, file a6318021-dc9f-482e-9367-ae35c2b7692a
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7
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Coronary Artery Stenting Affects Wall Shear Stress Topological Skeleton, file e384c434-6fd0-d4b2-e053-9f05fe0a1d67
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7
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Current and Future Applications of Computational Fluid Dynamics in Coronary Artery Disease, file 565b6292-a24f-4f60-9a65-aece64cc1fca
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6
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Application of an OCT-based 3D reconstruction framework to the hemodynamic assessment of an ulcerated coronary artery plaque, file e384c431-af46-d4b2-e053-9f05fe0a1d67
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6
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Impact of lower limb movement on the hemodynamics of femoropopliteal arteries: A computational study, file e384c432-e8d2-d4b2-e053-9f05fe0a1d67
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6
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Applications of computational fluid dynamics to congenital heart diseases: a practical review for cardiovascular professionals, file e384c434-050b-d4b2-e053-9f05fe0a1d67
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6
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Multicomponent Mechanical Characterization of Atherosclerotic Human Coronary Arteries: An Experimental and Computational Hybrid Approach, file e384c434-07dd-d4b2-e053-9f05fe0a1d67
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6
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Multiscale Computational Modeling of Vascular Adaptation: A Systems Biology Approach Using Agent-Based Models, file e384c434-307c-d4b2-e053-9f05fe0a1d67
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6
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A Multiscale Model of Atherosclerotic Plaque Development: Toward a Coupling Between an Agent-Based Model and CFD Simulations, file e384c431-8289-d4b2-e053-9f05fe0a1d67
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5
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Does clinical data quality affect fluid-structure interaction simulations of patient-specific stenotic aortic valve models?, file e384c431-9047-d4b2-e053-9f05fe0a1d67
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5
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Risk of myocardial infarction based on endothelial shear stress analysis using coronary angiography, file 03d9d4fa-d6e3-4c1a-90b6-12132028ce17
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4
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Design of innovative self-expandable femoral stents using inverse
homogenization topology optimization, file 24f78b44-3c1e-4e0f-9d09-9bf19095c504
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4
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Femoral artery hemodynamics: state of the art of computational analyses and future trends, file e384c431-4264-d4b2-e053-9f05fe0a1d67
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4
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Computing patient-specific hemodynamics in stented femoral artery models obtained from computed tomography using a validated 3D reconstruction method, file e384c431-c5c5-d4b2-e053-9f05fe0a1d67
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4
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Patient-specific computational simulation of coronary artery bifurcation stenting, file e384c434-2b55-d4b2-e053-9f05fe0a1d67
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4
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Fluid–Structure Interaction Model of a Percutaneous Aortic Valve: Comparison with an In Vitro Test and Feasibility Study in a Patient-Specific Case, file e384c434-c077-d4b2-e053-9f05fe0a1d67
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4
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Modelling coronary flows: impact of differently measured inflow boundary conditions on vessel-specific computational hemodynamic profiles, file f71aabaf-f7bc-4202-b058-610da489a663
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4
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Relationship between hemodynamics and in-stent restenosis in femoral arteries, file 2a130c29-314d-439f-ac1f-44b20421db45
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3
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Integrating particle tracking with computational fluid dynamics to assess haemodynamic perturbation by coronary artery stents, file 2e050d53-fa7c-407d-9841-260c258cd3f2
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3
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Computational fluid dynamics as supporting technology for coronary artery disease diagnosis and treatment: an international survey, file 3c907bd6-5311-4e29-ad6a-097c884a734e
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3
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Wall shear stress topological skeleton variability predicts plaque growth in human coronary arteries, file 44b1f2de-4d81-4cf2-ad7b-fb3fb7265fd2
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3
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Fluid dynamics and mass transport in lower limb vessels: Effects on restenosis, file 837ef69d-8c13-4afb-8d19-a442d6075f63
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3
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Multiscale agent-based modeling of restenosis after percutaneous transluminal angioplasty: Effects of tissue damage and hemodynamics on cellular activity, file 9c816835-c484-45ea-b0d8-9df35433cdce
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3
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The variability of wall shear stress topological skeleton predicts plaque growth in human coronary arteries, file d13946ff-2bf4-41d9-ab54-fadf41011edc
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3
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Modelling coronary flows: impact of differently measured inflow boundary conditions on vessel-specific computational hemodynamic profiles, file d27945fb-ca8e-4bf2-8f84-3077c17c7441
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3
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Risk of myocardial infarction based on endothelial shear stress analysis using coronary angiography, file deb09541-a2d6-43a1-bc10-61c7527e152c
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3
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Fluid–Structure Interaction Model of a Percutaneous Aortic Valve: Comparison with an In Vitro Test and Feasibility Study in a Patient-Specific Case, file e384c430-f039-d4b2-e053-9f05fe0a1d67
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3
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Application of an OCT-based 3D reconstruction framework to the hemodynamic assessment of an ulcerated coronary artery plaque, file e384c431-af47-d4b2-e053-9f05fe0a1d67
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3
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Transcatheter Aortic Valve with Embolic Filter: Experiments and Simulations, file e384c432-c494-d4b2-e053-9f05fe0a1d67
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3
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Effects of Vessel Tortuosity on Coronary Hemodynamics: An Idealized and Patient-Specific Computational Study, file e384c434-e787-d4b2-e053-9f05fe0a1d67
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3
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Divergence of the normalized wall shear stress as an effective computational template of low-density lipoprotein polarization at the arterial blood-vessel wall interface, file ebef1ee7-87a9-43ff-98f1-b2eb8edebda9
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3
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A predictive multiscale model of in-stent restenosis in femoral arteries: linking haemodynamics and gene expression with an agent-based model of cellular dynamics, file 0c70a495-bbaf-4597-aa4c-252b780932c1
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2
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Semi-Automatic Reconstruction of Patient-Specific Stented Coronaries based on Data Assimilation and Computer Aided Design, file 314f28d9-657b-433e-bdbf-3a1d6e4c4298
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2
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Is spontaneous coronary artery dissection (SCAD) related to local anatomy and hemodynamics? An exploratory study, file 34d0918e-a519-4ff2-820c-4ff47418ef6d
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2
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Editorial: Image-based computational approaches for personalized cardiovascular medicine: improving clinical applicability and reliability through medical imaging and experimental data, file 39430476-f8e3-4c34-ab94-a78107f4f1f5
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2
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Divergence of the normalized wall shear stress as an effective computational template of low-density lipoprotein polarization at the arterial blood-vessel wall interface, file 65615ad6-dd77-4d62-9702-3987b886b837
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2
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Smartphone-based particle image velocimetry for cardiovascular flows applications: a focus on coronary arteries, file 65e6e3c5-534a-4b1d-af32-278a099da332
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2
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Unveiling wall shear stress spatiotemporal heterogeneity in coronary arteries, file 6989927e-98ec-4afc-a7cc-7543fab2278e
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2
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Multi-objective design optimization of bioresorbable braided stents, file 96376aa9-5f4f-4b66-b6b9-ac5f5eb010ce
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2
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Aortic remodeling kinetics in response to coarctation-induced mechanical perturbations, file c3764c85-cea2-4d4b-bcc9-96c65d518d26
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2
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Computational investigation of the role of low-density lipoprotein and oxygen transport in atherosclerotic arteries, file caeee484-fe3f-4d18-8ba6-22c30cf9fd85
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2
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UNRAVELING THE BIOMECHANICS OF NITINOL BONE STAPLES: A COMBINED EXPERIMENTAL AND NUMERICAL INVESTIGATION, file e305720d-ab84-4871-be92-246a7709f22b
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2
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Modelling of blood flow in coronary stented arteries, file e384c430-de73-d4b2-e053-9f05fe0a1d67
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2
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Differences in rotational positioning and subsequent distal main branch rewiring of the Tryton stent: An optical coherence tomography and computational study, file e384c430-e29d-d4b2-e053-9f05fe0a1d67
|
2
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| Totale |
1.687 |
Archivio Istituzionale della Ricerca