Methods of computational modeling of coronary heart vessels for its digital twin

In this work, methods of numerical modelling of the coronary vessels system of the human heart have been studied. This investigation includes transient flow of the liquid – blood and dynamics of zones of shear stress at vessels. The main goal of the research is obtaining of hemodynamic and shear str...

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Main Authors: Naplekov, Ilya, Zheleznikov, Ivan, Pashchenko, Dmitry, Kobysheva, Polina, Moskvitina, Anna, Mustafin, Ravil, Gnutikova, Maria, Mullagalieva, Alina, Uzlov, Pavel
Format: Conference Proceeding
Language:English
Subjects:
Blood pressure
Blood vessels
Computational fluid dynamics
Digital twins
Energy consumption
Fluid flow
Heart
Heart diseases
Laminar flow
Mathematical models
Numerical methods
Reynolds number
Shear stress
Three dimensional flow
Turbulent flow
Two dimensional analysis
Two dimensional models
Unsteady flow
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Summary:In this work, methods of numerical modelling of the coronary vessels system of the human heart have been studied. This investigation includes transient flow of the liquid – blood and dynamics of zones of shear stress at vessels. The main goal of the research is obtaining of hemodynamic and shear stress for creating the digital twin of coronary heart vessels. The results were obtained for low Reynolds numbers about 20 of three-dimensional laminar flow. With this Reynolds number the turbulent flow of the blood is modelled by Realizable k-ε model, and SST models to the narrowing, expansions, and blocks inside the vessels. Loads caused by the additional energy consumption because of the turbulent flow of the blood (increase in arterial blood pressure) have been analyzed. A two-dimensional model of a separated vessel with fixed blood back-flow prevention is developed. Presence of a turbulent flow core is discovered. By the means of stress-strain properties of the model, visual representation of the wearing process of the blood back-flow preventer, and heart diseases progression is obtained.
ISSN:2261-236X
2274-7214
2261-236X
DOI:10.1051/matecconf/201817201009