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Download scientific diagram | The whole-heart geometry used for the simulation. On the left is the mesh of the heart clipped in the longitudinal axis. The thick layer with the coarser mesh surrounding the four chambers is the pericardial layer. Pictured on the right is the heart without the pericardial layer. from publication: Validating a Numerical Simulation of Human Heart Motion Using Clinical Data | Numerical simulations are increasingly often involved in developing new and improving existing medical therapies. While the models involved in those simulations are designed to resemble a specific phenomenon realistically, the results of the interplay of those models are | Motion, Heart and Numerical Simulation | ResearchGate, the professional network for scientists.
Research - Shadden Lab
A geometric multiscale model for the numerical simulation of blood flow in the human left heart
Linking statistical shape models and simulated function in the healthy adult human heart
PDF) Validating a Numerical Simulation of Human Heart Motion Using Clinical Data
Three-dimensional cardiac computational modelling: methods, features and applications, BioMedical Engineering OnLine
Fluids, Free Full-Text
Control of Whole Heart Geometry by Intramyocardial Mechano-Feedback: A Model Study
Heart blood flow simulation: a perspective review, BioMedical Engineering OnLine
A geometric multiscale model for the numerical simulation of blood flow in the human left heart
Ekaterina KOVACHEVA, Karlsruhe Institute of Technology, Karlsruhe, KIT, Institute of Biomedical Engineering (IBT)
GPU accelerated digital twins of the human heart open new routes for cardiovascular research
Control of Whole Heart Geometry by Intramyocardial Mechano-Feedback: A Model Study
Precision medicine in human heart modeling Biomechanics and Modeling in Mechanobiology
Numerical simulations of flow patterns in the human left ventricle model with a novel dynamic mesh morphing approach based on radial basis function - ScienceDirect
Control of Whole Heart Geometry by Intramyocardial Mechano-Feedback: A Model Study