PURPOSE: Atherosclerotic carotid plaques can be quantified in vivo by MRI. However, the accuracy in segmentation and quantification of components such as the thin fibrous cap (FC) and lipid-rich necrotic core (LRNC) remains unknown due to the lack of a submillimeter scale ground truth. METHODS: A novel approach was taken by numerically simulating in vivo carotid MRI providing a ground truth comparison. Upon evaluation of a simulated clinical protocol, MR readers segmented simulated images of cross-sectional plaque geometries derived from histological data of 12 patients. RESULTS: MR readers showed high correlation (R) and intraclass correlation (ICC) in measuring the luminal area (R = 0.996, ICC = 0.99), vessel wall area (R = 0.96, ICC = 0.94) and LRNC area (R = 0.95, ICC = 0.94). LRNC area was underestimated (mean error, -24%). Minimum FC thickness showed a mediocre correlation and intraclass correlation (R = 0.71, ICC = 0.69). CONCLUSION: Current clinical MRI can quantify carotid plaques but shows limitations for thin FC thickness quantification. These limitations could influence the reliability of carotid MRI for assessing plaque rupture risk associated with FC thickness. Overall, MRI simulations provide a feasible methodology for assessing segmentation and quantification accuracy, as well as for improving scan protocol design.
PURPOSE:Atherosclerotic carotid plaques can be quantified in vivo by MRI. However, the accuracy in segmentation and quantification of components such as the thin fibrous cap (FC) and lipid-rich necrotic core (LRNC) remains unknown due to the lack of a submillimeter scale ground truth. METHODS: A novel approach was taken by numerically simulating in vivo carotid MRI providing a ground truth comparison. Upon evaluation of a simulated clinical protocol, MR readers segmented simulated images of cross-sectional plaque geometries derived from histological data of 12 patients. RESULTS: MR readers showed high correlation (R) and intraclass correlation (ICC) in measuring the luminal area (R = 0.996, ICC = 0.99), vessel wall area (R = 0.96, ICC = 0.94) and LRNC area (R = 0.95, ICC = 0.94). LRNC area was underestimated (mean error, -24%). Minimum FC thickness showed a mediocre correlation and intraclass correlation (R = 0.71, ICC = 0.69). CONCLUSION: Current clinical MRI can quantify carotid plaques but shows limitations for thin FC thickness quantification. These limitations could influence the reliability of carotid MRI for assessing plaque rupture risk associated with FC thickness. Overall, MRI simulations provide a feasible methodology for assessing segmentation and quantification accuracy, as well as for improving scan protocol design.
Authors: Harm A Nieuwstadt; Aad van der Lugt; Zaid A M Kassar; Marcel Breeuwer; Anton F W van der Steen; Frank J H Gijsen Journal: Quant Imaging Med Surg Date: 2014-08
Authors: Arna van Engelen; Wiro J Niessen; Stefan Klein; Harald C Groen; Hence J M Verhagen; Jolanda J Wentzel; Aad van der Lugt; Marleen de Bruijne Journal: PLoS One Date: 2014-04-24 Impact factor: 3.240
Authors: Harm A Nieuwstadt; Zaid A M Kassar; Aad van der Lugt; Marcel Breeuwer; Anton F W van der Steen; Jolanda J Wentzel; Frank J H Gijsen Journal: PLoS One Date: 2015-04-09 Impact factor: 3.240
Authors: Annette M Kok; Aad van der Lugt; Hence J M Verhagen; Antonius F W van der Steen; Jolanda J Wentzel; Frank J H Gijsen Journal: J Biomech Date: 2017-07-05 Impact factor: 2.712