Summary
Coronary vascular disease(CVD) has been studied for many decades and has been found to be a very complex problem.
Despite dramatic medical advances over the last few decades, CVD remain a leading cause of death globally and the
number one cause of death in the European Union (EU). Inspite of the tedious and creative work by many expert scientists
from many different perspectives, the disease has only partially been understood. The approach that is taken here differs in
basic tenets from earlier approaches, in that it starts from a very basic system of study inorder to progressively build higher
levels of complexity. It is understood that the vast majority of the life threatening pathologies are associated with an
imbalance between the demand in oxygen and the supply provided by the RBCs. This project will start studying the structure
of the microvascular geometry and upscale the coronary circulation from there. The microvascular bed will be embedded into
a beating heart with all complexities associated with it:contracting muscle fibre, complex fibre architecture, valves, coronary
arteries and veins, etc. On that level, the project will multi-stage and multiscale with finite element (FE) modelling of
myocardial contraction, deformation and perfusion. The interdisciplinary perspective in this study is strong with contributions
from engineers, clinicians and biomaterial scientists. The scope of the study is usage of FE modelling for autoregulation of
coronary perfusion which extends the applications of FE model to common pathologies such as ischemic heart disease,
infarction or reperfusion issues and devices such as stents or cardiac assist devices, that improve coronary blood perfusion.
This project is in line with the European heart health charter to promote research in the field of cardiovascular diseases.
Despite dramatic medical advances over the last few decades, CVD remain a leading cause of death globally and the
number one cause of death in the European Union (EU). Inspite of the tedious and creative work by many expert scientists
from many different perspectives, the disease has only partially been understood. The approach that is taken here differs in
basic tenets from earlier approaches, in that it starts from a very basic system of study inorder to progressively build higher
levels of complexity. It is understood that the vast majority of the life threatening pathologies are associated with an
imbalance between the demand in oxygen and the supply provided by the RBCs. This project will start studying the structure
of the microvascular geometry and upscale the coronary circulation from there. The microvascular bed will be embedded into
a beating heart with all complexities associated with it:contracting muscle fibre, complex fibre architecture, valves, coronary
arteries and veins, etc. On that level, the project will multi-stage and multiscale with finite element (FE) modelling of
myocardial contraction, deformation and perfusion. The interdisciplinary perspective in this study is strong with contributions
from engineers, clinicians and biomaterial scientists. The scope of the study is usage of FE modelling for autoregulation of
coronary perfusion which extends the applications of FE model to common pathologies such as ischemic heart disease,
infarction or reperfusion issues and devices such as stents or cardiac assist devices, that improve coronary blood perfusion.
This project is in line with the European heart health charter to promote research in the field of cardiovascular diseases.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/898121 |
| Start date: | 01-02-2021 |
| End date: | 31-01-2023 |
| Total budget - Public funding: | 196 590,72 Euro - 196 590,00 Euro |
Cordis data
Original description
Coronary vascular disease(CVD) has been studied for many decades and has been found to be a very complex problem.Despite dramatic medical advances over the last few decades, CVD remain a leading cause of death globally and the
number one cause of death in the European Union (EU). Inspite of the tedious and creative work by many expert scientists
from many different perspectives, the disease has only partially been understood. The approach that is taken here differs in
basic tenets from earlier approaches, in that it starts from a very basic system of study inorder to progressively build higher
levels of complexity. It is understood that the vast majority of the life threatening pathologies are associated with an
imbalance between the demand in oxygen and the supply provided by the RBCs. This project will start studying the structure
of the microvascular geometry and upscale the coronary circulation from there. The microvascular bed will be embedded into
a beating heart with all complexities associated with it:contracting muscle fibre, complex fibre architecture, valves, coronary
arteries and veins, etc. On that level, the project will multi-stage and multiscale with finite element (FE) modelling of
myocardial contraction, deformation and perfusion. The interdisciplinary perspective in this study is strong with contributions
from engineers, clinicians and biomaterial scientists. The scope of the study is usage of FE modelling for autoregulation of
coronary perfusion which extends the applications of FE model to common pathologies such as ischemic heart disease,
infarction or reperfusion issues and devices such as stents or cardiac assist devices, that improve coronary blood perfusion.
This project is in line with the European heart health charter to promote research in the field of cardiovascular diseases.
Status
CLOSEDCall topic
MSCA-IF-2019Update Date
28-04-2024
Geographical location(s)
