| Nome |
# |
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Evaluation of Left Atrial Size and Function: Relevance for Clinical Practice, file e2913fdf-1101-f688-e053-3705fe0a67e0
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641
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Definitions for a common standard for 2D speckle tracking echocardiography: consensus document of the EACVI/ASE/Industry Task Force to standardize deformation imaging, file e2913fd9-4b4a-f688-e053-3705fe0a67e0
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413
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On estimating intraventricular hemodynamic forces from endocardial dynamics: A comparative study with 4D flow MRI, file e2913fdb-9b8a-f688-e053-3705fe0a67e0
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413
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Hemodynamic forces in the left and right ventricles of the human heart using 4D flow magnetic resonance imaging: Phantom validation, reproducibility, sensitivity to respiratory gating and free analysis software, file e2913fdc-4057-f688-e053-3705fe0a67e0
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273
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Precision Phenotyping in Heart Failure and Pattern Clustering of Ultrasound Data for the Assessment of Diastolic Dysfunction, file e2913fda-f724-f688-e053-3705fe0a67e0
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247
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Cardiac fluid dynamics anticipates heart adaptation, file e2913fd9-8d84-f688-e053-3705fe0a67e0
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202
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Cavitation phenomenon in mechanical prosthetic valves: Not only microbubbles, file e2913fdf-5032-f688-e053-3705fe0a67e0
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202
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Cardiac fluid dynamics meets deformation imaging, file e2913fdb-d621-f688-e053-3705fe0a67e0
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182
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Combined flow-based imaging assessment of optimal cardiac resynchronization therapy pacing vector: A case report, file e2913fdc-d508-f688-e053-3705fe0a67e0
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150
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Left Ventricular Response to Cardiac Resynchronization Therapy: Insights From Hemodynamic Forces Computed by Speckle Tracking, file e2913fdc-9bab-f688-e053-3705fe0a67e0
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143
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Analysis of mitral valve regurgitation by computational fluid dynamics, file e2913fdd-322e-f688-e053-3705fe0a67e0
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142
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Intraventricular flow patterns during right ventricular apical pacing, file e2913fdc-b9ad-f688-e053-3705fe0a67e0
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138
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Left ventricular pacing vector selection by novel echo-particle imaging velocimetry analysis for optimization of quadripolar cardiac resynchronization device: A case report, file e2913fda-8598-f688-e053-3705fe0a67e0
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137
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Principles of cardiovascular magnetic resonance feature tracking and echocardiographic speckle tracking for informed clinical use, file e2913fda-872d-f688-e053-3705fe0a67e0
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131
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Implantable Fiber Bragg Grating Sensor for Continuous Heart Activity Monitoring: Ex-Vivo and In-Vivo Validation, file e2913fde-e7b1-f688-e053-3705fe0a67e0
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126
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Cardiovascular magnetic resonance-derived left ventricular intraventricular pressure gradients among patients with precapillary pulmonary hypertension, file e2913fde-dd34-f688-e053-3705fe0a67e0
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109
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A new integrated approach to cardiac mechanics: reference values for normal left ventricle, file e2913fdf-0bc4-f688-e053-3705fe0a67e0
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90
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Assessment of Global Longitudinal and Circumferential Strain Using Computed Tomography Feature Tracking: Intra-Individual Comparison with CMR Feature Tracking and Myocardial Tagging in Patients with Severe Aortic Stenosis, file e2913fdc-dc6f-f688-e053-3705fe0a67e0
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84
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Clinical application of 2D speckle tracking strain for assessing cardio-toxicity in oncology, file e2913fdd-69b8-f688-e053-3705fe0a67e0
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74
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Computed tomography derived left ventricular inward displacement as a novel tool for quantification of segmental wall motion abnormalities, file e2913fdf-ba6e-f688-e053-3705fe0a67e0
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67
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Simplified mitral valve modeling for prospective clinical application of left ventricular fluid dynamics, file e2913fde-d71e-f688-e053-3705fe0a67e0
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66
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Impact of intraventricular haemodynamic forces misalignment on left ventricular remodelling after myocardial infarction, file e2913fdf-1798-f688-e053-3705fe0a67e0
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62
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Noninvasive Evaluation of Intraventricular Flow Dynamics by the HyperDoppler Technique: First Application to Normal Subjects, Athletes, and Patients with Heart Failure, file e2913fdf-7cd6-f688-e053-3705fe0a67e0
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61
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Influence of mitral valve elasticity on flow development in the left ventricle, file e2913fde-8ae4-f688-e053-3705fe0a67e0
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51
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Simultaneous Volumetric and Functional Assessment of the Right Ventricle in Hypoplastic Left Heart Syndrome After Fontan Palliation, Utilizing 3-Dimensional Speckle-Tracking Echocardiography, file e2913fdd-426e-f688-e053-3705fe0a67e0
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47
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The hemodynamic power of the heart differentiates normal from diseased right ventricles, file e2913fdf-b765-f688-e053-3705fe0a67e0
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45
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Impact of synchronous atrioventricular delay optimization on left ventricle flow force angle evaluated by echocardiographic particle image velocimetry, file b5a7e409-bbab-4b7c-ab50-38a55827ffde
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43
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Interplay between Geometry, Fluid Dynamics, and Structure in the Ventricles of the Human Heart, file abf1e97e-90b8-4e36-b2c1-9773317f4ba9
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39
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Comments on Defining the Contribution of Diastolic Vortex Ring to Left Ventricular Filling, file e2913fd9-8520-f688-e053-3705fe0a67e0
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37
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Comparative Analysis of Right Ventricle Fluid Dynamics, file e2913fde-9976-f688-e053-3705fe0a67e0
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37
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Range Variability in CMR Feature Tracking Multilayer Strain across Different Stages of Heart Failure, file e2913fdc-e986-f688-e053-3705fe0a67e0
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36
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Cardiac and Vascular Remodeling After 6 Months of Therapy With Sacubitril/Valsartan: Mechanistic Insights From Advanced Echocardiographic Analysis, file e2913fdf-7fae-f688-e053-3705fe0a67e0
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28
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Fluid flow in a helical vessel in presence of a stenosis, file e2913fde-a2bb-f688-e053-3705fe0a67e0
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26
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Analysis of the distribution and orientation of oxygenated and non-oxygenated blood in a double outlet right ventricle, file 6afb4b6d-d063-480f-ab74-3ca571d39880
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22
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Biomechanics in AIMETA, file e2913fdf-7e73-f688-e053-3705fe0a67e0
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21
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The Influence of Mitral Valve Asymmetry for an Improved Choice of Valve Repair or Replacement, file 1b83570c-8f8e-4f2b-ba53-eb3361388acb
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18
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Surrogate models provide new insights on metrics based on blood flow for the assessment of left ventricular function, file e2913fdf-7faf-f688-e053-3705fe0a67e0
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17
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Difference in cardiac remodeling between female athletes and pregnant women: a case control study, file e2913fdf-a8a9-f688-e053-3705fe0a67e0
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16
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Acute Modification of Hemodynamic Forces in Patients with Severe Aortic Stenosis after Transcatheter Aortic Valve Implantation, file d57df9ea-99de-4c14-b9a8-3c2ac44a3445
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14
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Cardiovascular outcomes in renal transplant recipients: Feasibility and clinical role of 2D speckle tracking to assess myocardial function, file e2913fdd-4f98-f688-e053-3705fe0a67e0
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14
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Introduction to Hemodynamic Forces Analysis: Moving Into the New Frontier of Cardiac Deformation Analysis, file e2913fde-9469-f688-e053-3705fe0a67e0
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14
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A Novel Approach to Left Ventricular Filling Pressure Assessment: The Role of Hemodynamic Forces Analysis, file e2913fde-c1a2-f688-e053-3705fe0a67e0
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14
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Haemodynamic forces predicting remodelling and outcome in patients with heart failure treated with sacubitril/valsartan, file 2605d91a-ed2a-438b-b9e4-7ec21429e9bb
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13
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Acute Modification of Hemodynamic Forces in Patients with Severe Aortic Stenosis after Transcatheter Aortic Valve Implantation, file b3a474d3-38ab-4aec-965f-cc9feed150c5
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13
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CMR-derived left ventricular intraventricular pressure gradients identify different patterns associated with prognosis in dilated cardiomyopathy, file 53debdee-20de-4d2e-a3e8-928f6f7f505a
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12
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Special issue on Advances in biomechanics: from foundations to applications, file e2913fdd-46d2-f688-e053-3705fe0a67e0
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12
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Changes in electrical activation modify the orientation of left ventricular flow momentum: novel observations using echocardiographic particle image velocimetry, file e2913fde-95d8-f688-e053-3705fe0a67e0
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12
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Fluid flow in a helical vessel in presence of a stenosis, file e2913fda-f714-f688-e053-3705fe0a67e0
|
10
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The effect of aortic root anatomy and vortex flow induced shear stress on the aortic valve leaflets, file c7bfb15d-bd64-46d9-b6be-f489dd1e1548
|
9
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Prognostic value of echocardiographic evaluation of cardiac mechanics in patients with aortic stenosis and preserved left ventricular ejection fraction, file 8e17c83e-91ed-4fd3-b543-2195c6b4a263
|
8
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Fluid flow in a helical vessel in presence of a stenosis, file e2913fd9-e229-f688-e053-3705fe0a67e0
|
8
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Reference ranges of left ventricular hemodynamic forces in healthy adults: A speckle-tracking echocardiographic study, file e2913fde-c85a-f688-e053-3705fe0a67e0
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8
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Effect of Aging on Intraventricular Kinetic Energy and Energy Dissipation, file 311e28ef-65bc-43bf-bda7-91bbfbfd8bb8
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7
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Cardiac fluid dynamics anticipates heart adaptation, file e2913fd9-204a-f688-e053-3705fe0a67e0
|
7
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Introduction to hemodynamic forces by echocardiography, file 9b71223f-fbf9-408f-a177-62d4eae23e3c
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6
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Home-based exercise program improves normal Right Ventricle function in Renal Transplant Recipients, file d9437169-99b7-4f20-9965-fda6a4146c3f
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6
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|
Changes in electrical activation modify the orientation of left ventricular flow momentum: novel observations using echocardiographic particle image velocimetry, file e2913fde-a3f7-f688-e053-3705fe0a67e0
|
6
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|
State of energy of ventricular flow: A cause or the first indicator of adverse remodeling?, file 171a11e5-3494-4172-ae0b-5267958905e0
|
5
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|
Simplified mitral valve modeling for prospective clinical application of left ventricular fluid dynamics, file e2913fdd-0d2b-f688-e053-3705fe0a67e0
|
5
|
|
Range Variability in CMR Feature Tracking Multilayer Strain across Different Stages of Heart Failure, file e2913fdd-121e-f688-e053-3705fe0a67e0
|
5
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The hemodynamic power of the heart differentiates normal from diseased right ventricles, file e2913fde-999c-f688-e053-3705fe0a67e0
|
5
|
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Home-based exercise program improves normal Right Ventricle function in Renal Transplant Recipients, file 367ecac2-b207-418f-b048-d3dedb1886d6
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4
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Prognostic value of echocardiographic evaluation of cardiac mechanics in patients with aortic stenosis and preserved left ventricular ejection fraction, file 41491617-08a3-4728-8139-259d5d138009
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4
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Ventricular Flow Profile in Young Patients with Single Left Ventricle Fontan using Echocardiographic Contrast Particle Imaging Velocimetry, file 52cfffa9-fe90-47df-92c6-731f7813550a
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4
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Contraction Patterns of Post-Fontan Single Right Ventricle versus Normal Left and Right Ventricles in Children: Insights from Principal Strain Analysis, file 566feb53-ef2f-443c-bba6-ae8e931fa7df
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4
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Changes in electrical activation modify the orientation of left ventricular flow momentum: novel observations using echocardiographic particle image velocimetry, file e2913fd9-8490-f688-e053-3705fe0a67e0
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4
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Differences in aortic vortex flow pattern between normal and patients with stroke: qualitative and quantitative assessment using transesophageal contrast echocardiography, file e2913fda-eac5-f688-e053-3705fe0a67e0
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4
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Intracardiac Flow Analysis: Techniques and Potential Clinical Applications, file e2913fdc-ce19-f688-e053-3705fe0a67e0
|
4
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Evaluation of Left Atrial Size and Function: Relevance for Clinical Practice, file e2913fdd-d504-f688-e053-3705fe0a67e0
|
4
|
|
Impact of synchronous atrioventricular delay optimization on left ventricle flow force angle evaluated by echocardiographic particle image velocimetry, file e2913fdf-a049-f688-e053-3705fe0a67e0
|
4
|
|
State of energy of ventricular flow: A cause or the first indicator of adverse remodeling?, file 84f84979-ad6d-4040-8937-c62fa1edd021
|
3
|
|
Ventricular Flow Profile in Young Patients with Single Left Ventricle Fontan using Echocardiographic Contrast Particle Imaging Velocimetry, file 9f265f27-44cc-4e99-a57a-3bbd8cf19b79
|
3
|
|
A new integrated approach to cardiac mechanics: reference values for normal left ventricle, file e2913fdd-c1c7-f688-e053-3705fe0a67e0
|
3
|
|
Cavitation phenomenon in mechanical prosthetic valves: Not only microbubbles, file e2913fdd-d4ff-f688-e053-3705fe0a67e0
|
3
|
|
Computed tomography derived left ventricular inward displacement as a novel tool for quantification of segmental wall motion abnormalities, file e2913fde-9f74-f688-e053-3705fe0a67e0
|
3
|
|
The effect of aortic root anatomy and vortex flow induced shear stress on the aortic valve leaflets, file e2913fde-a986-f688-e053-3705fe0a67e0
|
3
|
|
Abnormal Diastolic Hemodynamic Forces: A Link Between Right Ventricular Wall Motion, Intracardiac Flow, and Pulmonary Regurgitation in Repaired Tetralogy of Fallot, file 41aaeb86-1d06-4c1a-aa7e-67406561f9b3
|
2
|
|
Analysis of the distribution and orientation of oxygenated and non-oxygenated blood in a double outlet right ventricle, file 98b4bc40-d915-42e7-aa44-d89f554faa45
|
2
|
|
Home-based exercise program improves normal Right Ventricle function in Renal Transplant Recipients, file e2338610-6946-47ab-b72a-f59c5750f609
|
2
|
|
Tissue Tracking Technology for Assessing Cardiac Mechanics, file e2913fd9-d65a-f688-e053-3705fe0a67e0
|
2
|
|
Vortex imaging: new information gain from tracking cardiac energy loss, file e2913fda-8f99-f688-e053-3705fe0a67e0
|
2
|
|
Hemodynamic forces in a model left ventricle, file e2913fda-ecea-f688-e053-3705fe0a67e0
|
2
|
|
Influence of mitral valve elasticity on flow development in the left ventricle, file e2913fdc-6404-f688-e053-3705fe0a67e0
|
2
|
|
On the computation of hemodynamic forces in the heart chambers, file e2913fdc-dc78-f688-e053-3705fe0a67e0
|
2
|
|
Changes in electrical activation modify the orientation of left ventricular flow momentum: novel observations using echocardiographic particle image velocimetry, file e2913fde-3746-f688-e053-3705fe0a67e0
|
2
|
|
Fluid Mechanics for Cardiovascular Engineering, file e2913fde-9b57-f688-e053-3705fe0a67e0
|
2
|
|
Biomechanics in AIMETA, file c0dbbf11-639d-4bff-bfa0-5ccd276df6dc
|
1
|
|
Home-based exercise program improves normal Right Ventricle function in Renal Transplant Recipients, file d87a5652-0e24-49ce-b153-3d49e25b6ce1
|
1
|
|
. On the opening of a wall-mounted leaflet by a single flow pulse, file e2913fd9-0ce8-f688-e053-3705fe0a67e0
|
1
|
|
Experimental study of the asymmetric heart valve prototype., file e2913fd9-0d0b-f688-e053-3705fe0a67e0
|
1
|
|
Role of inertia in the interaction between oscillatory flow and a wall-mounted leaflet., file e2913fd9-0eb0-f688-e053-3705fe0a67e0
|
1
|
|
Emerging Trends in Clinical Assessment of Cardiovascular Fluid Dynamics., file e2913fd9-0ec8-f688-e053-3705fe0a67e0
|
1
|
|
Comparative numerical study on left ventricular fluid dynamics after dilated cardiomyopathy, file e2913fd9-19c2-f688-e053-3705fe0a67e0
|
1
|
|
Comments on Defining the Contribution of Diastolic Vortex Ring to Left Ventricular Filling, file e2913fd9-848a-f688-e053-3705fe0a67e0
|
1
|
|
Newer Methods to Assess Diastolic Function, file e2913fd9-90bc-f688-e053-3705fe0a67e0
|
1
|
|
Comparative numerical study on left ventricular fluid dynamics after dilated cardiomyopathy, file e2913fda-2e80-f688-e053-3705fe0a67e0
|
1
|
|
Cardiac resynchronization therapy by multipoint pacing improves response of left ventricular mechanics and fluid dynamics: a three-dimensional and particle image velocimetry echo study, file e2913fda-f729-f688-e053-3705fe0a67e0
|
1
|
|
Left and right ventricular hemodynamic forces in healthy volunteers and elite athletes assessed with 4D flow magnetic resonance imaging, file e2913fdb-0130-f688-e053-3705fe0a67e0
|
1
|
|
Three-Dimensional Principal Strain Analysis for Characterizing Subclinical Changes in Left Ventricular Function, file e2913fdb-9117-f688-e053-3705fe0a67e0
|
1
|
|
The Intraventricular Hemodynamic Forces Estimated Using Routine CMR Cine Images: A New Marker of the Failing Heart, file e2913fdc-941c-f688-e053-3705fe0a67e0
|
1
|
| Totale |
4.937 |