<p>Part 1: Biology, Physiopathology, Hemodynamics, Myogenic Responses and Clinical Intravascular Imaging of the Coronary Vascular Wall<br>1. Biomechanical Regulation of Endothelial Function in Atherosclerosis<br>2. Molecular mechanisms of the vascular responses to hemodynamic forces<br>3. Advanced atherosclerotic plaques in animal models versus human lesions: key elements to translation<br>4. Modeling the Glagov’s compensatory enlargement of human coronary atherosclerotic plaque<br>5. Measuring coronary arterial compliance and vasomotor response in clinical and research settings<br>6. Coronary intravascular ultrasound and optical coherence tomography imaging and clinical contexts in coronary hemodynamics<br>7. The interaction of biochemical, biomechanical and clinical factors of coronary disease: review and outlook</p><p>Part 2: Modeling Blood Flow in Arterial Branches and Bifurcations<br>8. Local blood flow parameters and atherosclerosis in coronary artery bifurcations<br>9. Effect of regional analysis methods on assessing the association between wall shear stress and coronary artery disease progression in the clinical setting<br>10. Hemodynamic disturbance due to serial stenosis in human coronary bifurcations: A computational fluid dynamics study<br>11. Hemodynamic perturbations due to the presence of stents<br>12. A new reduced-order model to assess the true fractional flow reserve of a left main coronary artery stenosis with downstream lesions and collateral circulations: an in vitro study</p><p>Part 3: Fluid-Structure Interaction, Stress Distribution and Plaque Rupture in Arterial Wall<br>13. In vitro, primarily microfluidic models for atherosclerosis<br>14. Prediction of the coronary plaque growth and vulnerability change by using patient-specific 3D FSI models based on intravascular ultrasound and optical coherence tomography follow-up data<br>15. Atheromatous plaque initiation and growth: a multiphysical process explored by an in-silico mass transport model<br>16. Emergent biomechanical factors predicting vulnerable coronary atherosclerotic plaque rupture<br>17. Microcalcifications and plaque rupture<br>18. Identification of coronary plaque mechanical properties from ex-vivo testing<br>19. Importance of residual stress and basal tone in healthy and pathological human coronary arteries</p><p>Part 4: Imaging Inflammatory Biomarkers for in vivo Intravascular Plaque Characterization<br>20. Intravascular ultrasound imaging of human coronary atherosclerotic plaque: novel morpho-elastic biomarkers of instability<br>21. Magnetic resonance elastography for arterial wall characterization<br>22. Noninvasive ultrafast ultrasound for imaging the coronary vasculature and assessing the arterial wall’s biomechanics<br>23. Pulse wave imaging for the mechanical assessment of atherosclerotic plaques</p><p>Part 5: Stenting, Coated Balloon, Drug Elution Systems and Modelling<br>24. Structure-function relation in the coronary artery tree: theory and applications in interventional cardiology<br>25. Sequential technique for the stenting of a coronary bifurcation: the re-proximal optimizing technique strategy<br>26. Modeling the stent deployment in coronary arteries and coronary bifurcations<br>27. The coated balloon protocol: An emergent clinical technique<br>28. Endovascular drug delivery and drug-elution systems</p>
