Presentation is loading. Please wait.

Presentation is loading. Please wait.

Multi-scale modeling of the carotid artery

Published byBennett Lawrence Modified over 8 years ago

Similar presentations

Presentation on theme: "Multi-scale modeling of the carotid artery"— Presentation transcript:

1 Multi-scale modeling of the carotid artery
G. Rozema, A.E.P. Veldman, N.M. Maurits University of Groningen, University Medical Center Groningen The Netherlands

2 Area of interest Atherosclerosis in the carotid arteries is a major cause of ischemic strokes! distal proximal ACI: internal carotid artery ACE: external carotid artery ACC: common carotid artery

3 A multi-scale computational model: Several submodels of different length- and timescales:
Carotid bifurcation A model for the local blood flow in the region of interest: A model for the fluid dynamics: ComFlo A model for the wall dynamics A model for the global cardiovascular circulation outside the region of interest (better boundary conditions) Fluid dynamics Wall dynamics Global Cardiovascular Circulation

4 Computational fluid dynamics: ComFlo
Finite-volume discretization of Navier-Stokes equations Cartesian Cut Cells method Domain covered with Cartesian grid Elastic wall moves freely through grid Discretization using apertures in cut cells Example: Continuity equation  Conservation of mass:

5 Boundary conditions Simple boundary conditions:
Future work: Deriving boundary conditions from lumped parameter models, i.e. modeling the cardiovascular circulation as an electric network (ODE) Outflow Outflow Inflow

6 The wall dynamics (1) Simple algebraic law: Independent rings model:
wr(z,t) and wz(z,t): displacement of vessel wall in radial and longitudinal direction Simple algebraic law: Independent rings model: Elasticity Pressure Inertia Elasticity Pressure

7 Wall dynamics (2) Generalized string model: Navier equations: Inertia
Shear Elasticity Damping Pressure Pressure Shear Inertia Elasticity

8 Modeling the wall as a mass-spring system
The wall is covered with pointmasses (markers) The markers are connected with springs For each marker a momentum equation is applied x: the vector of marker positions

9 The mass-spring system compared to the (simplified) Navier equations
Material points move in radial and longitudinal direction only Generalized string model Material points move in radial direction only Mass-spring system Material points (markers) are completely free: Conservation of momentum in all directions: Inertia Shear Pressure Elasticity Damping

10 Coupling the submodels
Carotid bifurcation Weak coupling between fluid equations (PDE) and wall equations (ODE) local and global hemodynamic submodels Future work: Numerical stability Fluid dynamics PDE wall motion pressure Wall dynamics ODE Boundary conditions Global Cardiovascular Circulation ODE

11 Results: clinical data and CFD
Example: Doppler flow wave form. Model variations: Rigid wall / elastic wall, Traction-free outflow / peripheral resistance A B C D Elastic wall No Yes Peripheral resistance

12 Results (2): Conclusion
Both elasticity and peripheral resistance must be taken into account to obtain a close resemblance between measured and calculated flow wave forms Future work: Clinical follow-up data 3D ultrasound Patient specific modeling

Download ppt "Multi-scale modeling of the carotid artery"

Similar presentations

My First Fluid Project Ryan Schmidt. Outline MAC Method How far did I get? What went wrong? Future Work.

My First Fluid Project Ryan Schmidt. Outline MAC Method How far did I get? What went wrong? Future Work.
S.Mukhin, N.Sosnin, V.Koshelev, A.Bunicheva, M.Abakymov, A.Khrulenko,

S.Mukhin, N.Sosnin, V.Koshelev, A.Bunicheva, M.Abakymov, A.Khrulenko,
Continuity Equation. Continuity Equation Continuity Equation Net outflow in x direction.

Continuity Equation. Continuity Equation Continuity Equation Net outflow in x direction.
Blood flow monitoring in cerebral vessels A. P. Chupakhin Lavrentyev Institute of Hydrodynamics, Novosibirsk, Russia Novosibirsk State University In collaboration.

Blood flow monitoring in cerebral vessels A. P. Chupakhin Lavrentyev Institute of Hydrodynamics, Novosibirsk, Russia Novosibirsk State University In collaboration.
Introduction: Gravitational forces resulting from microgravity, take off and landing of spacecraft are experienced by individual cells in the living organism.

Introduction: Gravitational forces resulting from microgravity, take off and landing of spacecraft are experienced by individual cells in the living organism.
C OMPUTATIONAL F LUID D YNAMIC M ODEL OF A RTERIOVENOUS F ISTULA A NASTOMOSIS TO S TUDY THE E FFECTS OF V ESSEL S IZE AND P RESSURE G RADIENT ON THE P.

C OMPUTATIONAL F LUID D YNAMIC M ODEL OF A RTERIOVENOUS F ISTULA A NASTOMOSIS TO S TUDY THE E FFECTS OF V ESSEL S IZE AND P RESSURE G RADIENT ON THE P.
Session: Computational Wave Propagation: Basic Theory Igel H., Fichtner A., Käser M., Virieux J., Seriani G., Capdeville Y., Moczo P.  The finite-difference.

Session: Computational Wave Propagation: Basic Theory Igel H., Fichtner A., Käser M., Virieux J., Seriani G., Capdeville Y., Moczo P.  The finite-difference.
An Introduction to Multiscale Modeling Scientific Computing and Numerical Analysis Seminar CAAM 699.

An Introduction to Multiscale Modeling Scientific Computing and Numerical Analysis Seminar CAAM 699.
Chapter 3 Biomechanics Concepts I

Chapter 3 Biomechanics Concepts I
1 MECH 221 FLUID MECHANICS (Fall 06/07) Tutorial 7.

1 MECH 221 FLUID MECHANICS (Fall 06/07) Tutorial 7.
Computational Mechanics & Numerical Mathematics University of Groningen Linking an artery to the circulation: Introducing a Quasi-Simultaneous Coupling.

Computational Mechanics & Numerical Mathematics University of Groningen Linking an artery to the circulation: Introducing a Quasi-Simultaneous Coupling.
A Numerical Simulation of the Vortex Ring Field Incurred by A Round Jet Rui Wang Advisor: Dr. Robin Shandas Department of Mechanical Engineering University.

A Numerical Simulation of the Vortex Ring Field Incurred by A Round Jet Rui Wang Advisor: Dr. Robin Shandas Department of Mechanical Engineering University.
12/21/2001Numerical methods in continuum mechanics1 Continuum Mechanics On the scale of the object to be studied the density and other fluid properties.

12/21/2001Numerical methods in continuum mechanics1 Continuum Mechanics On the scale of the object to be studied the density and other fluid properties.
Computational Mechanics & Numerical Mathematics University of Groningen Multi-scale modeling of the carotid artery G. Rozema, A.E.P. Veldman, N.M. Maurits.

Computational Mechanics & Numerical Mathematics University of Groningen Multi-scale modeling of the carotid artery G. Rozema, A.E.P. Veldman, N.M. Maurits.
1/36 Gridless Method for Solving Moving Boundary Problems Wang Hong Department of Mathematical Information Technology University of Jyväskyklä 28.05.2009.

1/36 Gridless Method for Solving Moving Boundary Problems Wang Hong Department of Mathematical Information Technology University of Jyväskyklä
Analyses and Simulation of Medicine Carrying Blood Flow in MATLAB

Analyses and Simulation of Medicine Carrying Blood Flow in MATLAB
Numerical methods for PDEs PDEs are mathematical models for –Physical Phenomena Heat transfer Wave motion.

Numerical methods for PDEs PDEs are mathematical models for –Physical Phenomena Heat transfer Wave motion.
MODEL STUDIES OF BLOOD FLOW IN BASILAR ARTERY WITH 3D LASER DOPPLER ANEMOMETER Biomedical Engineering Sergey Frolov, Tambov State Technical University,

MODEL STUDIES OF BLOOD FLOW IN BASILAR ARTERY WITH 3D LASER DOPPLER ANEMOMETER Biomedical Engineering Sergey Frolov, Tambov State Technical University,
FUNDAMENTAL EQUATIONS, CONCEPTS AND IMPLEMENTATION

FUNDAMENTAL EQUATIONS, CONCEPTS AND IMPLEMENTATION
1 CFD Analysis Process. 2 1.Formulate the Flow Problem 2.Model the Geometry 3.Model the Flow (Computational) Domain 4.Generate the Grid 5.Specify the.

1 CFD Analysis Process. 2 1.Formulate the Flow Problem 2.Model the Geometry 3.Model the Flow (Computational) Domain 4.Generate the Grid 5.Specify the.

Similar presentations

Ads by Google