TY - JOUR
T1 - Vulnerable atherosclerotic plaque elasticity reconstruction based on a segmentation-driven optimization procedure using strain measurements
T2 - Theoretical framework
AU - Floc'H, Simon Le
AU - Ohayon, Jacques
AU - Tracqui, Philippe
AU - Finet, Gérard
AU - Gharib, Ahmed M.
AU - Maurice, Roch L.
AU - Cloutier, Guy
AU - Pettigrew, Roderic I.
N1 - Funding Information:
Manuscript received November 19, 2008; revised December 26, 2008. First published January 19, 2009; current version published June 24, 2009. This work was supported in part by an appointment (J. Ohayon) to the Senior Fellow Program at the National Institutes of Health (NIH). This program is administered by Oak Ridge Institute for Science and Education through an interagency agreement between the NIH and the U.S. Department of Energy. The work of (J. Ohayon), P. Tracqui, G. Finet, and S. Le Floc’h was supported by grants from the Agence National de la Recherche, France (ANR 2006-2009, ATHEBIOMEC), the Rhône-Alpes (France) research cluster (I3M: Medical Images and Multiscale Models), Emergence 2005 and Explora’Doc 2006, Rhône-Alpes Region (France). Asterisk indicates corresponding author.
PY - 2009/7
Y1 - 2009/7
N2 - It is now recognized that prediction of the vulnerable coronary plaque rupture requires not only an accurate quantification of fibrous cap thickness and necrotic core morphology but also a precise knowledge of the mechanical properties of plaque components. Indeed, such knowledge would allow a precise evaluation of the peak cap-stress amplitude, which is known to be a good biomechanical predictor of plaque rupture. Several studies have been performed to reconstruct a Young's modulus map from strain elastograms. It seems that the main issue for improving such methods does not rely on the optimization algorithm itself, but rather on preconditioning requiring the best estimation of the plaque components' contours. The present theoretical study was therefore designed to develop: 1) a preconditioning model to extract the plaque morphology in order to initiate the optimization process, and 2) an approach combining a dynamic segmentation method with an optimization procedure to highlight the modulogram of the atherosclerotic plaque. This methodology, based on the continuum mechanics theory prescribing the strain field, was successfully applied to seven intravascular ultrasound coronary lesion morphologies. The re-constructed cap thickness, necrotic core area, calcium area, and the Young's moduli of the calcium, necrotic core, and fibrosis were obtained with mean relative errors of 12%, 4% and 1%, 43%, 32%, and 2%, respectively.
AB - It is now recognized that prediction of the vulnerable coronary plaque rupture requires not only an accurate quantification of fibrous cap thickness and necrotic core morphology but also a precise knowledge of the mechanical properties of plaque components. Indeed, such knowledge would allow a precise evaluation of the peak cap-stress amplitude, which is known to be a good biomechanical predictor of plaque rupture. Several studies have been performed to reconstruct a Young's modulus map from strain elastograms. It seems that the main issue for improving such methods does not rely on the optimization algorithm itself, but rather on preconditioning requiring the best estimation of the plaque components' contours. The present theoretical study was therefore designed to develop: 1) a preconditioning model to extract the plaque morphology in order to initiate the optimization process, and 2) an approach combining a dynamic segmentation method with an optimization procedure to highlight the modulogram of the atherosclerotic plaque. This methodology, based on the continuum mechanics theory prescribing the strain field, was successfully applied to seven intravascular ultrasound coronary lesion morphologies. The re-constructed cap thickness, necrotic core area, calcium area, and the Young's moduli of the calcium, necrotic core, and fibrosis were obtained with mean relative errors of 12%, 4% and 1%, 43%, 32%, and 2%, respectively.
KW - Coronary arteries
KW - Elastography
KW - Inverse problem
KW - Linear elasticity
KW - Modulography
KW - Vulnerable plaques
UR - http://www.scopus.com/inward/record.url?scp=67649518725&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=67649518725&partnerID=8YFLogxK
U2 - 10.1109/TMI.2009.2012852
DO - 10.1109/TMI.2009.2012852
M3 - Article
C2 - 19164080
AN - SCOPUS:67649518725
SN - 0278-0062
VL - 28
SP - 1126
EP - 1137
JO - IEEE Transactions on Medical Imaging
JF - IEEE Transactions on Medical Imaging
IS - 7
M1 - 4752741
ER -