Published online before print November 8, 2004, doi: 10.1161/01.CIR.0000147287.23741.9A
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(Circulation. 2004;110:3239-3244.)
© 2004 American Heart Association, Inc.
Imaging |
Differentiation of Intraplaque Versus Juxtaluminal Hemorrhage/Thrombus in Advanced Human Carotid Atherosclerotic Lesions by In Vivo Magnetic Resonance Imaging
From the Department of Radiology, University of Washington (A.K., M.S.F., W.S.K., B.C., T.S., C.Y.), Seattle, Wash; Department of Surgery, University of Washington and VA Puget Sound Health Care System (T.S.H.), Seattle, Wash; The Mountain-Whisper-Light Statistical Consulting (N.L.P.), Seattle, Wash; and Department of Radiology, University of Heidelberg (A.K.), Heidelberg, Germany.
Correspondence to Chun Yuan, Professor, University of Washington, Department of Radiology, 1959 NE Pacific Ave, Box 357115, Seattle, WA 98195. E-mail cyuan{at}u.washington.edu
Received December 12, 2003; de novo received April 20, 2004; revision received June 16, 2004; accepted June 17, 2004.
Background— Intraplaque hemorrhage and juxtaluminal hemorrhage/thrombus may differ in cause and clinical implications. This study tested the hypothesis that MRI can distinguish between intraplaque hemorrhage and juxtaluminal hemorrhage/thrombus and investigated the association between hemorrhage and underlying lesion types.
Methods and Results— Twenty-six patients scheduled for carotid endarterectomy were imaged with a 1.5-T GE scanner by a multicontrast-weighted MRI technique. Hemorrhages were identified with previously established MRI criteria, and differentiations were made between intraplaque and juxtaluminal hemorrhage/thrombus. Corresponding histology was used to confirm the magnetic resonance findings. Tissues underlying areas of hemorrhage/thrombus were histologically categorized according to modified American Heart Association criteria. Of 190 matched sections, 140 contained areas of hemorrhage by histology, of which MRI correctly detected 134. The sensitivity and specificity for MRI to correctly identify cross sections that contained hemorrhage were 96% and 82%, respectively. Furthermore, MRI was able to distinguish juxtaluminal hemorrhage/thrombus from intraplaque hemorrhage with an accuracy of 96%. The distribution of lesion types underlying hemorrhages differed significantly (P=0.004). Intraplaque hemorrhage had an underlying lipid-rich type IV/V lesion in 55% of histological sections, whereas juxtaluminal hemorrhage/thrombus had an underlying calcified lesion type VII in 70% of sections.
Conclusions— In vivo high-resolution MRI can detect and differentiate intraplaque hemorrhage from juxtaluminal hemorrhage/thrombus with good accuracy. The association of hemorrhage and lesion types suggests potential differences in origin. Noninvasive MRI therefore provides a possible tool for prospectively studying differences in origin of plaque hemorrhage and the association of plaque progression and instability.
Key Words: magnetic resonance imaging • atherosclerosis • carotid arteries • plaque • hemorrhage
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