<div><p>Geometry of the heart adapts to mechanical load, imposed by pressures and volumes of the cavities. We regarded preservation of cardiac geometry as a homeostatic control system. The control loop was simulated by a chain of models, starting with geometry of the cardiac walls, sequentially simulating circulation hemodynamics, myofiber stress and strain in the walls, transfer of mechano-sensed signals to structural changes of the myocardium, and finalized by calculation of resulting changes in cardiac wall geometry. Instead of modeling detailed mechano-transductive pathways and their interconnections, we used principles of control theory to find optimal transfer functions, representing the overall biological responses to mechanical sign...
A multiscale model of the cardiovascular system (CVS) in which the left ventricle (LV) of the heart ...
Mathematical modelling of the human heart and its function can expand our understanding of various c...
Deformation and structure of the cardiac wall can be assessed non-invasively by imaging techniques s...
Geometry of the heart adapts to mechanical load, imposed by pressures and volumes of the cavities. W...
In the cardiac left ventricle during systole mechanical load of the myocardial fibers is distributed...
In the cardiac left ventricle during systole mechanical load of the myocardial fibers is distributed...
The uniformity of the mechanical load of the cardiac fibers in the wall is maintained by continuous ...
Mathematical models provide a suitable platform to test hypotheses on the relation between local mec...
Abstract While the heart is a dynamic organ and one of its major functions is to provide the organis...
The development of cardiac models that faithfully recapitulate heart conditions is the goal of cardi...
With circulatory pathology, patient-specific simulation of hemodynamics is required to minimize inva...
The heart is structurally and functionally a highly non-homogenous organ, yet its main function as a...
The heart pumps blood into circulation against vascular resistance and actively regulates the contra...
A multiscale model of the cardiovascular system (CVS) in which the left ventricle (LV) of the heart ...
Mathematical modelling of the human heart and its function can expand our understanding of various c...
Deformation and structure of the cardiac wall can be assessed non-invasively by imaging techniques s...
Geometry of the heart adapts to mechanical load, imposed by pressures and volumes of the cavities. W...
In the cardiac left ventricle during systole mechanical load of the myocardial fibers is distributed...
In the cardiac left ventricle during systole mechanical load of the myocardial fibers is distributed...
The uniformity of the mechanical load of the cardiac fibers in the wall is maintained by continuous ...
Mathematical models provide a suitable platform to test hypotheses on the relation between local mec...
Abstract While the heart is a dynamic organ and one of its major functions is to provide the organis...
The development of cardiac models that faithfully recapitulate heart conditions is the goal of cardi...
With circulatory pathology, patient-specific simulation of hemodynamics is required to minimize inva...
The heart is structurally and functionally a highly non-homogenous organ, yet its main function as a...
The heart pumps blood into circulation against vascular resistance and actively regulates the contra...
A multiscale model of the cardiovascular system (CVS) in which the left ventricle (LV) of the heart ...
Mathematical modelling of the human heart and its function can expand our understanding of various c...
Deformation and structure of the cardiac wall can be assessed non-invasively by imaging techniques s...