Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry
Aortic stenosis is the most common valvular heart disease with a prevalence of 2% among individuals over 65 years and 4% over 80, in developed countries. Accurate valve assessment for intervention timing is critical. Using only routinely obtained clinical data, this research aims to present accurate...
| Main Author: | |
|---|---|
| Format: | Others |
| Published: |
North Dakota State University
2017
|
| Online Access: | https://hdl.handle.net/10365/26625 |
| id |
ndltd-ndsu.edu-oai-library.ndsu.edu-10365-26625 |
|---|---|
| record_format |
oai_dc |
| spelling |
ndltd-ndsu.edu-oai-library.ndsu.edu-10365-266252021-09-28T17:11:37Z Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry Traeger, Brad James Aortic stenosis is the most common valvular heart disease with a prevalence of 2% among individuals over 65 years and 4% over 80, in developed countries. Accurate valve assessment for intervention timing is critical. Using only routinely obtained clinical data, this research aims to present accurate recreations of in vivo transvalvular hemodynamics using computational fluid dynamics (CFD) and validate Gorlin formula and echocardiography (echo)/continuity techniques. The in vivo valve was compared to simplified and idealized geometries. Instantaneous anatomic orifice area (AOA<sub>max</sub>) was underestimated by about 40% by Gorlin's formula and (dP<sub>mean</sub>). Time-averaged orifice area (EOA<sub>mean</sub>), by an echo/continuity, was about 40% smaller than the AOA<sub>max</sub>. The Gorlin formula better assesses AOA<sub>max</sub> using (dP<sub>mean eff</sub>). dP<sub>mean eff</sub> is required for Gorlin formula approximation of AOA<sub>max</sub> and echo/continuity overestimates EOA<sub>mean</sub> with increasing error for lower flow rates. Correlations between EOA and AOA should only be made as instantaneous or only time-averaged comparisons. 2017-10-15T19:05:23Z 2017-10-15T19:05:23Z 2012 text/thesis https://hdl.handle.net/10365/26625 NDSU Policy 190.6.2 https://www.ndsu.edu/fileadmin/policy/190.pdf application/pdf North Dakota State University |
| collection |
NDLTD |
| format |
Others
|
| sources |
NDLTD |
| description |
Aortic stenosis is the most common valvular heart disease with a prevalence of 2% among individuals over 65 years and 4% over 80, in developed countries. Accurate valve assessment for intervention timing is critical. Using only routinely obtained clinical data, this research aims to present accurate recreations of in vivo transvalvular hemodynamics using computational fluid dynamics (CFD) and validate Gorlin formula and echocardiography (echo)/continuity techniques. The in vivo valve was compared to simplified and idealized geometries. Instantaneous anatomic orifice area (AOA<sub>max</sub>) was underestimated by about 40% by Gorlin's formula and (dP<sub>mean</sub>). Time-averaged orifice area (EOA<sub>mean</sub>), by an echo/continuity, was about 40% smaller than the AOA<sub>max</sub>. The Gorlin formula better assesses AOA<sub>max</sub> using (dP<sub>mean eff</sub>). dP<sub>mean eff</sub> is required for Gorlin formula approximation of AOA<sub>max</sub> and echo/continuity overestimates EOA<sub>mean</sub> with increasing error for lower flow rates. Correlations between EOA and AOA should only be made as instantaneous or only time-averaged comparisons. |
| author |
Traeger, Brad James |
| spellingShingle |
Traeger, Brad James Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry |
| author_facet |
Traeger, Brad James |
| author_sort |
Traeger, Brad James |
| title |
Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry |
| title_short |
Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry |
| title_full |
Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry |
| title_fullStr |
Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry |
| title_full_unstemmed |
Assessment of Native Aortic Stenosis Hemodynamics and Clinical Evaluation Methods Using Steady State Computational Fluid Dynamics and Computed Tomography-Derived Geometry |
| title_sort |
assessment of native aortic stenosis hemodynamics and clinical evaluation methods using steady state computational fluid dynamics and computed tomography-derived geometry |
| publisher |
North Dakota State University |
| publishDate |
2017 |
| url |
https://hdl.handle.net/10365/26625 |
| work_keys_str_mv |
AT traegerbradjames assessmentofnativeaorticstenosishemodynamicsandclinicalevaluationmethodsusingsteadystatecomputationalfluiddynamicsandcomputedtomographyderivedgeometry |
| _version_ |
1719485555253706752 |