Assessment of vulnerable plaque composition by matching the deformation of a parametric plaque model to measured plaque deformation
| Autor: | Frits Mastik, C.W.J. Oomens, Johannes A. Schaar, R.A. Baldewsing, A.F.W. van der Steen |
|---|---|
| Přispěvatelé: | Cardiology, Mechanical Engineering |
| Jazyk: | angličtina |
| Rok vydání: | 2005 |
| Předmět: |
medicine.medical_specialty
Materials science Arteriosclerosis Young's modulus Pressure differential In Vitro Techniques medicine.disease_cause Risk Assessment Sensitivity and Specificity Severity of Illness Index Imaging phantom symbols.namesake Imaging Three-Dimensional Nuclear magnetic resonance Risk Factors Image Interpretation Computer-Assisted Cadaver medicine Humans Carotid Stenosis Computer Simulation Electrical and Electronic Engineering Ultrasonography Interventional Radiological and Ultrasound Technology Phantoms Imaging Models Cardiovascular Reproducibility of Results Stress distribution Image Enhancement Vulnerable plaque Elasticity Computer Science Applications Local radial symbols Radiology Radial stress Algorithms Software Lipid pool |
| Zdroj: | IEEE Transactions on Medical Imaging, 24(4), 514-528. Institute of Electrical and Electronics Engineers Inc. IEEE Transactions on Medical Imaging, 24(4), 514-528. Institute of Electrical and Electronics Engineers |
| ISSN: | 0278-0062 |
| Popis: | Intravascular ultrasound (IVUS) elastography visualizes local radial strain of arteries in so-called elastograms to detect rupture-prone plaques. However, due to the unknown arterial stress distribution these elastograms cannot be directly interpreted as a morphology and material composition image. To overcome this limitation we have developed a method that reconstructs a Young's modulus image from an elastogram. This method is especially suited for thin-cap fibroatheromas (TCFAs), i.e., plaques with a media region containing a lipid pool covered by a cap. Reconstruction is done by a minimization algorithm that matches the strain image output, calculated with a parametric finite element model (PFEM) representation of a TCFA, to an elastogram by iteratively updating the PFEM geometry and material parameters. These geometry parameters delineate the TCFA media, lipid pool and cap regions by circles. The material parameter for each region is a Young's modulus, E/sub M/, E/sub L/, and E/sub C/, respectively. The method was successfully tested on computer-simulated TCFAs (n=2), one defined by circles, the other by tracing TCFA histology, and additionally on a physical phantom (n=1) having a stiff wall (measured E/sub M/=16.8 kPa) with an eccentric soft region (measured E/sub L/=4.2 kPa). Finally, it was applied on human coronary plaques in vitro (n=1) and in vivo (n=1). The corresponding simulated and measured elastograms of these plaques showed radial strain values from 0% up to 2% at a pressure differential of 20, 20, 1, 20, and 1 mmHg respectively. The used/reconstructed Young's moduli [kPa] were for the circular plaque E/sub L/=50/66, E/sub M/=1500/1484, E/sub C/=2000/2047, for the traced plaque E/sub L/=25/1, E/sub M/=1000/1148, E/sub C/=1500/1491, for the phantom E/sub L/=4.2/4 kPa, E/sub M/=16.8/16, for the in vitro plaque E/sub L/=n.a./29, E/sub M/=n.a./647, E/sub C/=n.a./1784 kPa and for the in vivo plaque E/sub L/=n.a./2, E/sub M/=n.a./188, E/sub C/=n.a./188 kPa. |
| Databáze: | OpenAIRE |
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