Imaging the Intracranial Atherosclerotic Vessel Wall Using 7T MRI: Initial Comparison with Histopathology

In this preliminary study, 7T imaging was capable of identifying not only intracranial wall thickening but different plaque components such as foamy macrophages and collagen. Signal heterogeneity was typical of advanced atherosclerotic disease. BACKGROUND AND PURPOSE: Several studies have attempted to characterize intracranial atherosclerotic plaques by using MR imaging sequences. However, dedicated validation of these sequences with histology has not yet been performed. The current study assessed the ability of ultra-high-resolution 7T MR imaging sequences with different image contrast weightings to image plaque components, by using histology as criterion standard. MATERIALS AND METHODS: Five specimens of the circle of Wills were imaged at 7T with 0.11 × 0.11 mm in-plane-resolution proton attenuation–, T1-, T2-, and T2*-weighted sequences (through-plane resolution, 0.11–1 mm). Tissue samples from 13 fiducial-marked locations (per specimen) on MR imaging underwent histologic processing and atherosclerotic plaque classification. Reconstructed MR images were matched with histologic sections at corresponding locations. RESULTS: Forty-four samples were available for subsequent evaluation of agreement or disagreement between plaque components and image contrast differences. Of samples, 52.3% (n = 23) showed no image contrast heterogeneity; this group comprised solely no lesions or early lesions. Of samples, 25.0% (n = 11, mostly advanced lesions) showed good correlation between the spatial organization of MR imaging heterogeneities and plaque components. Areas of foamy macrophages were generally seen as proton attenuation–, T2-, and T2*- hypointense areas, while areas of increased collagen content showed more ambiguous signal intensities. Five samples showed image-contrast heterogeneity without corresponding plaque components on histology; 5 other samples showed contrast heterogeneity based on intima-media artifacts. CONCLUSIONS: MR imaging at 7T has the image contrast capable of identifying both focal intracranial vessel wall thickening and distinguishing areas of different signal intensities spatially corresponding to plaque components within more advanced atherosclerotic plaques.

[1]  V. Fuster,et al.  Multimodality imaging of atherosclerotic plaque activity and composition using FDG-PET/CT and MRI in carotid and femoral arteries. , 2009, Atherosclerosis.

[2]  Andrew G. Webb,et al.  Origin and reduction of motion and f0 artifacts in high resolution T2*-weighted magnetic resonance imaging: Application in Alzheimer's disease patients , 2010, NeuroImage.

[3]  P. Amarenco,et al.  Basilar Artery Atherosclerotic Plaques in Paramedian and Lacunar Pontine Infarctions: A High-Resolution MRI Study , 2010, Stroke.

[4]  P. Morgan,et al.  Intraplaque Hemorrhage in Symptomatic Intracranial Atherosclerotic Disease , 2011, Journal of neuroimaging : official journal of the American Society of Neuroimaging.

[5]  Chun Yuan,et al.  In vivo accuracy of multisequence MR imaging for identifying unstable fibrous caps in advanced human carotid plaques , 2003, Journal of magnetic resonance imaging : JMRI.

[6]  P. Van de Moortele,et al.  Intracranial-Derived Atherosclerosis Assessment: An In Vitro Comparison between Virtual Histology by Intravascular Ultrasonography, 7T MRI, and Histopathologic Findings , 2013, American Journal of Neuroradiology.

[7]  Eckart Fleck,et al.  Experimental evaluation of the detectability of submillimeter atherosclerotic lesions in ex vivo human iliac arteries with ultrahigh-field (7.0 T) magnetic resonance imaging , 2006, The International Journal of Cardiovascular Imaging.

[8]  Ewoud J. Smit,et al.  Multi-sequence whole-brain intracranial vessel wall imaging at 7.0 tesla , 2013, European Radiology.

[9]  W. Kerwin,et al.  The vulnerable, or high-risk, atherosclerotic plaque: noninvasive MR imaging for characterization and assessment. , 2007, Radiology.

[10]  Peter R Luijten,et al.  Imaging Intracranial Vessel Wall Pathology With Magnetic Resonance Imaging: Current Prospects and Future Directions , 2014, Circulation.

[11]  D. Mikulis,et al.  Intracranial Atherosclerotic Plaque Enhancement in Patients with Ischemic Stroke , 2013, American Journal of Neuroradiology.

[12]  Peter R Luijten,et al.  Direct detection of myocardial fibrosis by MRI. , 2011, Journal of molecular and cellular cardiology.

[13]  N. Petridou,et al.  Pushing the limits of high‐resolution functional MRI using a simple high‐density multi‐element coil design , 2013, NMR in biomedicine.

[14]  Peter R Luijten,et al.  Intracranial Vessel Wall Imaging at 7.0-T MRI , 2011, Stroke.

[15]  R. Virmani,et al.  Lessons from sudden coronary death: a comprehensive morphological classification scheme for atherosclerotic lesions. , 2000, Arteriosclerosis, thrombosis, and vascular biology.

[16]  Alfons G H Kessels,et al.  Assessment of human atherosclerotic carotid plaque components with multisequence MR imaging: initial experience. , 2005, Radiology.

[17]  H. Kabasawa,et al.  Evaluating middle cerebral artery atherosclerotic lesions in acute ischemic stroke using magnetic resonance T1-weighted 3-dimensional vessel wall imaging. , 2014, Journal of stroke and cerebrovascular diseases : the official journal of National Stroke Association.

[18]  David J Mikulis,et al.  Intracranial vasa vasorum: insights and implications for imaging. , 2013, Radiology.

[19]  J. Hendrikse,et al.  Current status of clinical magnetic resonance imaging for plaque characterisation in patients with carotid artery stenosis. , 2013, European journal of vascular and endovascular surgery : the official journal of the European Society for Vascular Surgery.

[20]  High-resolution magnetic resonance imaging reveals hidden etiologies of symptomatic vertebral arterial lesions. , 2014, Journal of stroke and cerebrovascular diseases : the official journal of National Stroke Association.

[21]  Zahi A Fayad,et al.  Atherothrombosis and high-risk plaque: Part II: approaches by noninvasive computed tomographic/magnetic resonance imaging. , 2005, Journal of the American College of Cardiology.

[22]  Chun Yuan,et al.  Classification of Human Carotid Atherosclerotic Lesions With In Vivo Multicontrast Magnetic Resonance Imaging , 2002, Circulation.

[23]  W S Kerwin,et al.  In Vivo Accuracy of Multispectral Magnetic Resonance Imaging for Identifying Lipid-Rich Necrotic Cores and Intraplaque Hemorrhage in Advanced Human Carotid Plaques , 2001, Circulation.

[24]  Zheng-yu Jin,et al.  Plaque Distribution of Stenotic Middle Cerebral Artery and Its Clinical Relevance , 2011, Stroke.

[25]  L. Caplan,et al.  Intracranial atherosclerosis , 2014, The Lancet.

[26]  Z. Rumboldt,et al.  High-resolution MRI of basilar atherosclerosis: three-dimensional acquisition and FLAIR sequences , 2012, Brain and behavior.

[27]  Anne L. Martel,et al.  Characterization of Complicated Carotid Plaque With Magnetic Resonance Direct Thrombus Imaging in Patients With Cerebral Ischemia , 2003, Circulation.

[28]  K. Ogasawara,et al.  Predicting Carotid Plaque Characteristics Using Quantitative Color-Coded T1-Weighted MR Plaque Imaging: Correlation with Carotid Endarterectomy Specimens , 2014, American Journal of Neuroradiology.

[29]  Imaging of Intracranial Plaques with Black‐Blood Double Inversion Recovery MR Imaging and CT , 2011, Journal of neuroimaging : official journal of the American Society of Neuroimaging.

[30]  X. Lou,et al.  Contrast-Enhanced 3T High-Resolution MR Imaging in Symptomatic Atherosclerotic Basilar Artery Stenosis , 2013, American Journal of Neuroradiology.

[31]  C Yuan,et al.  Carotid atherosclerotic plaque: noninvasive MR characterization and identification of vulnerable lesions. , 2001, Radiology.