3D CFD simulation of intracranial aneurysm
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Transcript of 3D CFD simulation of intracranial aneurysm
A CFD Approach to Quantifying the Hemodynamic Forces in Giant
Cerebral Aneurysms
Anna Hoppe1, Brian Walsh1
1Department of Biomedical Engineering, University of Iowa
Dr. Ching-Long Lin2
2Department of Mechanical Engineering,
University of Iowa
The Hemodynamics of Aneurysms
What is an aneurysm?
A localized, blood-filled dilation of a blood vessel caused by
disease or weakening of the vessel wall3
The diagnostic implications:4
1) High risk of hemorrhage
- causing stroke or death
- mortality rate: 68% (after 2 yrs.), 85% (after 5 yrs.)
2) Cerebral compression or distal thromboembolism
- leading to progressive neurologic deficits
The Hemodynamics of Aneurysms and Its Therapeutic Implications
An understanding of the hemodynamics within a particular aneurysm could aid:4
- a prediction of when rupture is likely to occur- assessment of possible treatment options
Therapeutic treatments are dependent upon aneurysm geometry4
Possible Aneurysm Geometries
Figure 1: Illustration of a saccular aneurysm6
Figure 2: Illustration of a fusiform aneurysm5
Therapeutic Treatment Options
• Stent used for artery reconstruction4
– Used for saccular aneurysms– Dangerous with giant fusiform aneurysms (> 25 mm
in diameter)• Coil Embolization Technique4
– Used for saccular aneurysms– Dangerous with giant fusiform aneurysms
Figure 3: Illustration of the coiling technique2
Therapeutic Treatment Options
• Surgically remove the aneurysm4
– Only done with saccular aneurysms
• Occlude a proximal supplying artery to the aneurysm4
– Most commonly done with giant fusiform aneurysms– NO quantitative validation for using this method
• A CFD approach for quantitative validation is outlined in an article in AJNR by Jou, L., et al.
Quantitative Validation for Proximal Artery Occlusion
• A CFD approach for quantitative validation of proximal artery occlusion:– Article in Am. J. of Neuroradiology by Jou, L., et al.4
– Determined velocity field, wall shear stress and pressure distribution within a giant saccular cerebral aneurysm of a patient (MR image)4
• Before and after simulated proximal artery occlusion4 • Conclusion:4
– Important to know hemodynamic conditions when planning treatment– Flow patterns: dependent upon flow in each feeding artery
» May not improve the long-term stability of the aneurysm
Our Project: Quantitative Validation for Proximal Artery Occlusion
Use a patient-specific aneurysm geometry to determine the affect of proximal artery occlusion on:
Wall shear stressPressure distributionVelocity (in the aneurysm sac)
To answer the question: Is proximal artery occlusion a valid treatment option for giant aneurysms (does it reduce hemodynamic forces in the aneurysm sac)?
In general: We would also like to compare wall shear stress, pressure distribution, and velocity in diseased artery with and without the proximal feeding artery occluded.
We obtained:- patient-specific MR image of a saccular aneurysm in the Circle of Willis in the brain - courtesy of Professor Raghavan, Dept. of Biomedical Engineering at the U of I
Our Project: Quantitative Validation for Proximal Artery Occlusion
• Like the article by Jou, L., et al.4 – Our MR image is a saccular aneurysm and is in the same
general location in the brain• In the article: aneurysm occurred off the basilar artery (feeds
into the Circle of Willis)4 • Our saccular aneurysm: occurred in the Circle of Willis
Figure 4: Illustration of the Circle of Willis in the human brain1
Methods
• Meshing started with an STL file.• Using Magics software hard edges were removed• Once the STL was loaded into Gambit the surface mesh
was deleted, leaving just a surface.• Next the edges, faces and volume were created then
meshed; yielding a volumetric mesh. Boundary conditions:– Inlets- Velocity Inlet– Outlets- Outflow– Aneurysm body- Wall– No slip condition assumed (See Figure 5)
Material: Blood(assumed to be Newtonian fluid)Viscosity: .0035 PoiseDensity: 1056 kg/ m3
Time: TransientModel: k-omega
Methods (cont.)
Outlet25 Nodes
Velocity Inlet 75 Nodes
Outlet50 Nodes
Velocity Inlet25 Nodes
Velocity Inlet50 Nodes
Wall Figure 5: Geometry of aneurysm used in simulation
Each of the three inlets was occluded by changing the boundary condition from velocity inlet to wall in order to examine the effects on the velocity vectors, pressure, and wall shear stress in the aneurysm.
Secondary Boundary Conditions:
Assumptions
• Rigid Walls– Valid because the aneurysm is approximately twice as
stiff as other vessels due lack of elastin.– Yields higher WSS values than an actual patient
• Steady flow at peak systole(60 cm/s)– Yields maximum hemodynamic forces which have the
most clinical relevance• Velocity vectors normal to inlet surface
• Assumed to be turbulent flow because Re72413(1.056 )(60 )(0.4 )
Re0.0035
g cmcmvd cm s
gcm s
• Scheme– SIMPLE
• Spatial Discretization– Gradient- Least Squares Cell Based– Pressure- Standard– Momentum- second order upwind– Turbulent Kinetic Energy- Second Order Upwind– Specific Dissipation Rate- Second Order Upwind
• Transient Formulation– Second Order Implicit
Solution Methods
• Calculations– Time Step- .1 seconds– Number of Time Steps- 10– Iterations/Time Step- 20
Pressure Distribution Unoccluded Aneurysm Blocked Large Inlet
Blocked Medium Inlet Blocked Small Inlet
Wall Shear Stress Distribution Unoccluded Aneurysm Blocked Large Inlet
Blocked Medium Inlet Blocked Small Inlet
Velocity Distribution No Blocked Inlets
Velocity Distribution Blocked Large Inlet
Velocity Distribution Blocked Medium Inlet
Velocity Distribution Blocked Small Inlet
Is Proximal Artery Occlusion A Valid Treatment Option?
Pressure Distribution (in aneurysm sac)
- Unoccluded aneurysm: ≈ 959 Pa
- Blocked small inlet: 202 Pa – 927 Pa
- Blocked medium inlet: -7.71 Pa – 233 Pa
- Blocked large inlet: -5.23 Pa – 116 Pa
The unoccluded aneurysm had the highest pressure distribution. Blocking the small inlet increased the pressure distribution to a level similar to that before occlusion.
Increased pressure within aneurysms has been known to lead to subsequent aneurysm growth4
Thus, blocking the medium and large inlets constitute a better treatment modality from a pressure standpoint. Choosing which feeding artery to block is highly geometry dependent.4
Jou, L., et al. found: prior to proximal artery occlusion, increased pressure distribution due to primary flow diversion
Findings by Jou, L., et al.
(A) Calculated velocity field (m/s). Note highly asymmetric flow secondary to near occlusion of the right vertebral artery. There is a large region of slow re-circulating flow (blue) in the pouch of the aneurysm.
(B) Calculated distribution of pressure (range from 0 to 150 Pascal). The pressure distribution has no regions of pronounced increased pressure, with a smooth drop from inlet to outlet vessels.
Is Proximal Artery Occlusion A Valid Treatment Option?
Wall Shear Stress (WSS) Distribution (in aneurysm sac)
- Unoccluded aneurysm: ≈ 0 – 4.39 Pa
- Blocked small inlet: 0 Pa – 3.66 Pa
- Blocked medium inlet: 0 Pa – 2.06 Pa
- Blocked large inlet: 0 Pa – 1.14 Pa
The unoccluded aneurysm had the highest WSS distribution. Blocking the small inlet increased the WSS distribution to a level similar to that before occlusion.
Increased WSS within aneurysms has been known to lead to endothelial cell lining damage4
Thus, blocking the medium and large inlets constitute a better treatment modality from a WSS standpoint
Jou, L., et al. found: prior to proximal artery occlusion, increased WSS due to primary flow diversion
Is Proximal Artery Occlusion A Valid Treatment Option?
Velocity Distribution (in aneurysm sac)
- Unoccluded aneurysm: large re-circulating flow region, high velocity out of small outlet
- Blocked small inlet: large re-circulating flow region, high velocity out of small outlet
- Blocked medium inlet: large re-circulating flow region, high velocity out of small outlet
- Blocked large inlet: large re-circulating flow region, high velocity out of small outlet
The velocity and flow recirculation patterns are not largely effected by sacrificing any of the proximal feeding arteries however the velocity magnitudes are decreased by proximal atery
occlusion
Is Proximal Artery Occlusion A Valid Treatment Option?
Due to the high dependence of geometry on blood flow patterns within an aneurysm, sacrificing a proximal feeding artery is a viable treatment modality in limited cases, to be determined on a patient-specific basis.
References
[1] The A.D.A.M Editorial Team . Stroke Image. Retrieved November 29, 2009, from The How Stuff Works website: healthguide.howstuffworks.com/stroke-picture-....
[2] The AVM Foundation. What is Embolization? Retrieved November 29, 2009, from The AVM Foundation: www.avmfoundation.org/index.php?go=learn:avm:....
[3] Houghton Mifflin Company. (2007). The American Heritage® Medical Dictionary. Houghton Mifflin Harcourt Publishing Company.
References (continued)
[4] Jou, L., et al. (2003). Computational Approach to Quantifying Hemodynamic Forces in Giant Cerebral Aneurysms [Electronic Version.] American Journal of Neuroradiology , 24, 1804-1810.
[5] The University Hospital. Types of Stroke. Retrieved November 28, 2009, from The University Hospital: www.theuniversityhospital.com/stroke/types.htm.
[6] University of Illinois College of Medicine. (2007). What is a Brain Aneurysm? Retrieved November 28, 2009, from The University of Illinois College of Medicine website: chicago.medicine.uic.edu/.../brain_aneurysm/.