Nome |
# |
Biodegradable magnesium coronary stents: Material, design and fabrication, file e0c31c08-be67-4599-e053-1705fe0aef77
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594
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Applicability assessment of a stent-retriever thrombectomy finite-element model, file e0c31c10-2ec0-4599-e053-1705fe0aef77
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349
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On the necessity of modelling fluid–structure interaction for stented coronary arteries, file e0c31c0d-d4d2-4599-e053-1705fe0aef77
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254
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Fatigue behaviour of Nitinol peripheral stents: The role of plaque shape studied with computational structural analyses, file e0c31c0d-e95a-4599-e053-1705fe0aef77
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229
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A framework for computational fluid dynamic analyses of patient-specific stented coronary arteries from optical coherence tomography images, file e0c31c0b-23d2-4599-e053-1705fe0aef77
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217
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Design rules for producing cardiovascular stents by selective laser melting: Geometrical constraints and opportunities, file e0c31c0e-6329-4599-e053-1705fe0aef77
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199
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Evaluation of an aortic valve prosthesis: Fluid-structure interaction or structural simulation?, file e0c31c0a-eb0b-4599-e053-1705fe0aef77
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193
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The Effect of Modified Blalock-Taussig Shunt Size and Coarctation Severity on Coronary Perfusion After the Norwood Operation, file e0c31c0d-55d7-4599-e053-1705fe0aef77
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183
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Expert recommendations on the assessment of wall shear stress in human coronary arteries: existing methodologies, technical considerations, and clinical applications, file e0c31c0e-5da4-4599-e053-1705fe0aef77
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168
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Reconstruction of stented coronary arteries from optical coherence tomography images: Feasibility, validation, and repeatability of a segmentation method, file e0c31c0a-f45c-4599-e053-1705fe0aef77
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161
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From histology and imaging data to models for in-stent restenosis, file e0c31c0d-93b5-4599-e053-1705fe0aef77
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159
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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 e0c31c0c-0bac-4599-e053-1705fe0aef77
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158
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Numerical blood flow simulation in surgical corrections: what do we need for an accurate analysis?, file e0c31c0d-7004-4599-e053-1705fe0aef77
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158
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Modeling and Experimental Studies of Coating Delamination of Biodegradable Magnesium Alloy Cardiovascular Stents, file e0c31c10-d7d4-4599-e053-1705fe0aef77
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157
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Superficial femoral artery stenting: Impact of stent design and overlapping on the local hemodynamics, file 9a78d504-7a6d-4c74-ad34-3375c737776a
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152
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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 e0c31c10-8b91-4599-e053-1705fe0aef77
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146
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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 94895043-ff15-4d85-aa8d-2587014f0683
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144
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Design and functional testing of a novel balloon-expandable cardiovascular stent in CoCr alloy produced by selective laser melting, file e0c31c0f-4c18-4599-e053-1705fe0aef77
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144
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Virtual bench testing to study coronary bifurcation stenting, file e0c31c0e-b289-4599-e053-1705fe0aef77
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143
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Thrombus mechanics: How can we contribute to improve diagnostics and treatment?, file 2a1137df-b24b-4576-8f09-b29bec516c02
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136
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Automatic segmentation of optical coherence tomography pullbacks of coronary arteries treated with bioresorbable vascular scaffolds: Application to hemodynamics modeling, file e0c31c0c-ca03-4599-e053-1705fe0aef77
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133
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Healthy and diseased coronary bifurcation geometries influence near-wall and intravascular flow: A computational exploration of the hemodynamic risk, file e0c31c11-a9c3-4599-e053-1705fe0aef77
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132
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Influence of plaque calcifications on coronary stent fracture: A numerical fatigue life analysis including cardiac wall movement, file e0c31c0d-3acb-4599-e053-1705fe0aef77
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131
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Selective laser melting of NiTi stents with open-cell and variable diameter, file e0c31c11-9a13-4599-e053-1705fe0aef77
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120
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Computational Modeling to Predict Fatigue Behavior of NiTi Stents: What Do We Need?, file e0c31c07-bf33-4599-e053-1705fe0aef77
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117
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Patient-specific computer modelling of coronary bifurcation stenting: The John Doe programme, file e0c31c0e-9892-4599-e053-1705fe0aef77
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117
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Self-expandable stent for thrombus removal modeling: Solid or beam finite elements?, file e482ea11-b6ec-4f54-8336-9a9d0a4a6b08
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114
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Development of biodegradable magnesium alloy stents with coating, file e0c31c08-1b49-4599-e053-1705fe0aef77
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113
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A multiscale model for the study of cardiac biomechanics in single-ventricle surgeries: A clinical case, file e0c31c08-2490-4599-e053-1705fe0aef77
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106
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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 e0c31c0c-5852-4599-e053-1705fe0aef77
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105
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Computational Study of Axial Fatigue for Peripheral Nitinol Stents, file e0c31c0d-cf8e-4599-e053-1705fe0aef77
|
103
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Multiscale Computational Modeling of Vascular Adaptation: A Systems Biology Approach Using Agent-Based Models, file e0c31c11-d3be-4599-e053-1705fe0aef77
|
101
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Can finite element models of ballooning procedures yield mechanical response of the cardiovascular site to overexpansion?, file e0c31c0a-366f-4599-e053-1705fe0aef77
|
98
|
Numerical model of a valvuloplasty balloon: in vitro validation in a rapid‑prototyped phantom, file e0c31c09-4842-4599-e053-1705fe0aef77
|
96
|
Development of a patient-specific cerebral vasculature fluid-structure-interaction model, file 0c1cebd3-6f3b-434c-a09c-b883d7d7ddc0
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95
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Evaluation of segmentation accuracy and its impact on patient-specific CFD analysis, file e0c31c12-5e8c-4599-e053-1705fe0aef77
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94
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Semi-Automatic Reconstruction of Patient-Specific Stented Coronaries based on Data Assimilation and Computer Aided Design, file dd93a42d-4d34-4b13-8958-8a7430448921
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87
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Pledget-Armed Sutures Affect the Haemodynamic Performance of Biologic Aortic Valve Substitutes: A Preliminary Experimental and Computational Study, file e0c31c0a-dc24-4599-e053-1705fe0aef77
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86
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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 e0c31c0c-c8d2-4599-e053-1705fe0aef77
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84
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Contribution of Mechanical and Fluid Stresses to the Magnitude of In-stent Restenosis at the Level of Individual Stent Struts, file e0c31c0d-a86c-4599-e053-1705fe0aef77
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82
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In vivo and in vitro evaluation of a biodegradable magnesium vascular stent designed by shape optimization strategy, file e0c31c11-651b-4599-e053-1705fe0aef77
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82
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A numerical finite element methodology of the EVAR procedure, file d23095cc-622d-4885-828d-0c5120aa366f
|
76
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Biomechanical Impact of Wrong Positioning of a Dedicated Stent for Coronary Bifurcations: A Virtual Bench Testing Study, file e0c31c0d-7b85-4599-e053-1705fe0aef77
|
73
|
Biomechanical Modeling to Improve Coronary Artery Bifurcation Stenting: Expert Review Document on Techniques and Clinical Implementation, file e0c31c0e-b3a7-4599-e053-1705fe0aef77
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68
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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 b79dca8b-3655-4e60-b0a3-953fde19bc4a
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65
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An integrated approach to patient-specific predictive modeling for single ventricle heart palliation, file e0c31c0d-c632-4599-e053-1705fe0aef77
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65
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Multiscale agent-based modeling of restenosis after percutaneous transluminal angioplasty: Effects of tissue damage and hemodynamics on cellular activity, file 0d8065b6-2af4-4025-ace0-09b75843ea85
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63
|
Computing patient-specific hemodynamics in stented femoral artery models obtained from computed tomography using a validated 3D reconstruction method, file 84b5a606-2ae7-4243-80bd-7078910be8e5
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63
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Is modeling stents still an important issue?, file e0c31c0e-728f-4599-e053-1705fe0aef77
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61
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Finite Element Simulations of the ID Venous System to Treat Venous Compression Disorders: From Model Validation to Realistic Implant Prediction, file e0c31c10-e2c3-4599-e053-1705fe0aef77
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61
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Validation and Verification of High-Fidelity Simulations of Thoracic Stent-Graft Implantation, file 8c902a61-d35c-4990-bf65-bcfb7f4c2c28
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60
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The first virtual patient-specific thrombectomy procedure, file e0c31c11-7915-4599-e053-1705fe0aef77
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60
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3D reconstruction of coronary artery bifurcations from coronary angiography and optical coherence tomography: feasibility, validation, and reproducibility, file e0c31c10-ad74-4599-e053-1705fe0aef77
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58
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A Multiscale Model of Atherosclerotic Plaque Development: Toward a Coupling Between an Agent-Based Model and CFD Simulations, file 3f9f753a-03aa-4f34-adc4-f674172211e0
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55
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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 e0c31c0d-6ba7-4599-e053-1705fe0aef77
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55
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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 e0c31c0f-6870-4599-e053-1705fe0aef77
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54
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A numerical investigation to evaluate the washout of blood compartments in a total artificial heart, file e595b457-9245-445b-8ba9-390806b93cc3
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50
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First report on free expansion simulations of a dedicated bifurcation stent mounted on a stepped balloon, file e0c31c0e-7b9e-4599-e053-1705fe0aef77
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47
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Patient-specific computational simulation of coronary artery bifurcation stenting, file e0c31c11-6055-4599-e053-1705fe0aef77
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44
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Multiscale Modeling of Superior Cavopulmonary Circulation: Hemi-Fontan and Bidirectional Glenn Are Equivalent, file e0c31c12-956e-4599-e053-1705fe0aef77
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43
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Baseline local hemodynamics as predictor of lumen remodeling at 1-year follow-up in stented superficial femoral arteries, file e0c31c10-5708-4599-e053-1705fe0aef77
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41
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Patient-specific multi-scale design optimization of transcatheter aortic valve stents, file 2cc5c6f7-c518-4dd6-9857-d6a0b1e09667
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40
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Relationship between hemodynamics and in-stent restenosis in femoral arteries, file a75c26a0-5930-412c-82d0-7062b71b2eba
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40
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Integration of Clinical Data Collected at Different Times for Virtual Surgery in Single Ventricle Patients: A Case Study, file e0c31c0e-7f90-4599-e053-1705fe0aef77
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39
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Applicability analysis to evaluate credibility of an in silico thrombectomy procedure, file e0c31c11-7916-4599-e053-1705fe0aef77
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38
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A COMPUTATIONAL STUDY TO INVESTIGATE DEBONDING IN COATED BIORESORBABLE STENTS, file e0c31c0e-7b99-4599-e053-1705fe0aef77
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36
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Multicomponent Mechanical Characterization of Atherosclerotic Human Coronary Arteries: An Experimental and Computational Hybrid Approach, file e0c31c11-9faf-4599-e053-1705fe0aef77
|
36
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Understanding TAVR device expansion as it relates to morphology of the bicuspid aortic valve: A simulation study, file e0c31c11-b513-4599-e053-1705fe0aef77
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36
|
Local fluid dynamics in patients with bifurcated coronary lesions undergoing percutaneous coronary interventions, file e0c31c11-3c52-4599-e053-1705fe0aef77
|
35
|
Nickel–Titanium peripheral stents: Which is the best criterion for the multi-axial fatigue strength assessment?, file e0c31c12-9fbf-4599-e053-1705fe0aef77
|
35
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Local blood flow patterns in stented coronary bifurcations: an experimental and numerical study, file e0c31c0e-7d36-4599-e053-1705fe0aef77
|
34
|
In-Stent Restenosis Progression in Human Superficial Femoral Arteries: Dynamics of Lumen Remodeling and Impact of Local Hemodynamics, file e0c31c12-0f81-4599-e053-1705fe0aef77
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32
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Impact of the Internal Carotid Artery Morphology on in silico Stent-Retriever Thrombectomy Outcome, file e0c31c11-b693-4599-e053-1705fe0aef77
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28
|
Experiments and numerical simulations to evaluate peeling properties of polymeric coatings for degradable Mg stents, file e0c31c08-b013-4599-e053-1705fe0aef77
|
27
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Plaque Mechanics, file e0c31c0d-7cb3-4599-e053-1705fe0aef77
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26
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How to Validate in silico Deployment of Coronary Stents: Strategies and Limitations in the Choice of Comparator, file e0c31c12-4ac2-4599-e053-1705fe0aef77
|
26
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Effect of working environment and procedural strategies on mechanical performance of bioresorbable vascular scaffolds, file e0c31c10-dae6-4599-e053-1705fe0aef77
|
24
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Femoral artery hemodynamics: state of the art of computational analyses and future trends, file e0c31c0e-d7e1-4599-e053-1705fe0aef77
|
22
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In silico thrombectomy trials for acute ischemic stroke, file 2dddc975-eecb-47c8-a862-3ed7f64fc4f3
|
21
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Computational Modeling of Pathophysiologic Responses to Exercise in Fontan Patients, file e0c31c0e-7de9-4599-e053-1705fe0aef77
|
20
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Moving Along: In biomechanics, rehabilitation engineering, and movement analysis, Italian researchers are making great strides, file e0c31c0e-9bdc-4599-e053-1705fe0aef77
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19
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A low dimensional surrogate model for a fast estimation of strain in the thrombus during a thrombectomy procedure, file 7a4c67c4-7587-48f3-a263-db89fe36fb58
|
16
|
3D modelling of drug-coated balloons for the treatment of calcified superficial femoral arteries, file e0c31c11-8984-4599-e053-1705fe0aef77
|
13
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Use of computer models in cardiovascular therapy to advance precision medicine, file bbec50b9-4beb-4c4b-a1de-a392bbf0b91c
|
12
|
Double-Kissing Nanocrush for Bifurcation Lesions: Development, Bioengineering, Fluid Dynamics, and Initial Clinical Testing, file e0c31c10-0189-4599-e053-1705fe0aef77
|
8
|
The Effect of Modified Blalock-Taussig Shunt Size and Coarctation Severity on Coronary Perfusion After the Norwood Operation, file e0c31c08-1b4b-4599-e053-1705fe0aef77
|
7
|
Generation of a Virtual Cohort of Patients for in Silico Trials of Acute Ischemic Stroke Treatments, file 34628c8a-8e5b-4e1c-9b09-28479e252563
|
6
|
Applicability assessment for in-silico patient-specific TEVAR procedures, file df822006-ac1d-45d5-96c6-3aacd74e9760
|
6
|
Combined stent-retriever and aspiration intra-arterial thrombectomy performance for fragmentable blood clots: A proof-of-concept computational study, file a8cb4320-1b66-4ccf-a9a4-9035d83f07b7
|
5
|
An integrated approach to patient-specific predictive modeling for single ventricle heart palliation, file e0c31c08-2196-4599-e053-1705fe0aef77
|
5
|
Healthy and diseased coronary bifurcation geometries influence near-wall and intravascular flow: A computational exploration of the hemodynamic risk, file e0c31c0a-f5f0-4599-e053-1705fe0aef77
|
5
|
An interactive simulation tool for patient-specific clinical decision support in single-ventricle physiology, file e0c31c0b-8d01-4599-e053-1705fe0aef77
|
5
|
Modeling and Experimental Studies of Coating Delamination of Biodegradable Magnesium Alloy Cardiovascular Stents, file e0c31c0c-ea8f-4599-e053-1705fe0aef77
|
4
|
In vivo and in vitro evaluation of a biodegradable magnesium vascular stent designed by shape optimization strategy, file e0c31c0d-cb8d-4599-e053-1705fe0aef77
|
4
|
From patient-specific data to multiscale hemodynamics simulations: the challenge of boundary conditions., file e0c31c07-ffa6-4599-e053-1705fe0aef77
|
3
|
Influence of plaque calcifications on coronary stent fracture: A numerical fatigue life analysis including cardiac wall movement, file e0c31c08-1795-4599-e053-1705fe0aef77
|
3
|
Different Finite Element Strategies to Satisfy Clinical and Engineering Requirements in Modeling a Novel Percutaneous DeviceASME 2012 Summer Bioengineering Conference, Parts A and B, file e0c31c08-1d82-4599-e053-1705fe0aef77
|
3
|
Biomechanical Impact of Wrong Positioning of a Dedicated Stent for Coronary Bifurcations: A Virtual Bench Testing Study, file e0c31c0c-4f53-4599-e053-1705fe0aef77
|
3
|
Utilizing numerical simulations to prevent stent graft kinking during thoracic endovascular aortic repair, file e1f91cca-61a2-4e1d-836c-d3472179cd0a
|
3
|
Investigating the effect of drug release on in-stent restenosis: A hybrid continuum – agent-based modelling approach, file 3c430f44-6bc0-409c-b024-6345ba4a746f
|
2
|
Totale |
8.129 |