Imaging of the Carotid Artery Vulnerable Plaque
- 4.1k Downloads
Atherosclerosis involving the carotid arteries has a high prevalence in the population worldwide. This condition is significant because accidents of the carotid artery plaque are associated with the development of cerebrovascular events. For this reason, carotid atherosclerotic disease needs to be diagnosed and those determinants that are associated to an increased risk of stroke need to be identified. The degree of stenosis typically has been considered the parameter of choice to determine the therapeutical approach, but several recently published investigations have demonstrated that the degree of luminal stenosis is only an indirect indicator of the atherosclerotic process and that direct assessment of the plaque structure and composition may be key to predict the development of future cerebrovascular ischemic events. The concept of “vulnerable plaque” was born, referring to those plaque’s parameters that concur to the instability of the plaque making it more prone to the rupture and distal embolization. The purpose of this review is to describe the imaging characteristics of “vulnerable carotid plaques.”
KeywordsCarotid artery Vulnerable plaque CTA MRA US-ECD
Atherosclerosis involving the carotid arteries is a disease with a high prevalence in the population, particularly in elderly patients, and carotid artery narrowing has been reported in up to 75 % of men and 62 % of women aged 65 years . Atherosclerotic disease of the carotid arteries is a significant condition as accidents of the carotid artery plaques have been associated with the development of cerebrovascular events . For this reason, detection of carotid atherosclerotic disease and identification of those determinants that are associated to an increased risk of stroke are critical components to the prevention of stroke.
The degree of luminal stenosis typically has been considered as the most important element to grade the severity of carotid atherosclerotic disease. However, several recent investigations have demonstrated that the plaque structure and composition may represent a more direct biomarker for the development of cerebrovascular ischemic events [3, 4, 5, 6]. From a conceptual point of view, this is easy to understand: the majority of ischemic infarcts occur because emboli originating from the heart or a carotid plaque occlude an arterial vessel of the brain and not because there is a reduced blood flow from a luminal stenosis, usually well-compensated thanks to the Circle of Willis and other cerebral collateralization.
In the late 1980s, coronary artery angiographic studies showed that coronary artery plaques causing only a moderate degree of stenosis can lead to an acute myocardial infarction [7, 8], confirming that luminal narrowing was not the cause of the myocardial infarction. Histopathological studies demonstrated that erosion and disruption was present in those plaques associated with myocardial infarction. Similar conclusions were reached for the carotid arteries as studies found that cerebrovascular events also can occur in patients with carotid plaques causing low-grade stenosis (<30 %) and with no other identifiable cause for their stroke [9, 10, 11].
AHA classification and imaging techniques
Incorporation of scattered macrophages and foam cells within the arterial wall triggered by intralesional atherogenic lipoprotein
Development of fatty streaks
Extracellular fats that break up cell–cell connections in smooth muscle layers
The classic atheroma that contains a fatty necrotic core. The presence of atheroma may not narrow the vascular lumen since that the affected vessels can compensate for the increase in plaque volume through a widening of their external circumference rather than protrusion of plaque into the vascular lumen
Stage V is further classified as three different classes: Stage Va indicates those plaques having a fatty core as well as a multilayered thick fibrous cap (fibroatheroma); Stage Vb lesions are largely calcified; and Stage Vc lesions are predominantly fibrous
“Complex” plaque: there are areas of internal haemorrhage or focal apposition thrombosis. These lesions may undergo repeated cycles of rupture, thrombosis, and remodelling
The Concept of Vulnerable Plaque and its Clinical Impact
A number of carotid plaque features have been associated with an increase risk of stroke [16, 17], whereas others are associated with a reduced risk of ischemic events . Howard et al. found that different types of plaque are associated with different types of ischemic events. Carotid plaques from patients treated with endarterectomy because of previous ocular ischemic events have fewer vulnerable plaque features than those from patients with recent cerebral ischemic events, possibly explaining some of the differences in risk of stroke between these groups .
Plaque Surface Morphology
Several studies compared different imaging techniques to assess carotid plaque ulcerations [26, 27], and the best imaging modality for this purpose is CTA [22, 28, 29]. Saba et al. [22, 28] showed in 2007 that CTA had significantly better sensitivity compared to US-ECD for the detection of plaque ulcerations (93 vs. 37.5 %). The use of post-processing techniques, especially volume-rendering algorithms, may further help in the detection\characterization of carotid plaque ulcerations . One of the limitations of CTA in the assessment and detection of small ulcerations is the presence of a halo or edge blur that may mask these ulcers [30, 31].
MRI can detect the presence of carotid plaque ulcerations with sensitivity similar to the CTA . In a recently published paper by Etesami et al. , contrast-enhancement MR was superior to time-of-flight (TOF) MRA for the detection of carotid ulcerations; the latter has a sensitivity of only 55 %, whereas contrast-enhancement MR has a sensitivity of 81.5 %. The false negatives on TOF MRA were related to ulcer orientation, location relative to point of maximum stenosis, and neck-to-depth ratio.
The Fibrous Cap
The FC plays a critical role in determining vulnerability of atherosclerotic plaques; particularly, the thickness and morphology are important predictors of rupture. Histologically, the FC is constituted by smooth muscle cells within a collagen-proteoglycan matrix associated with macrophages and T lymphocytes . Inflammatory cells are also present at the interface with the underlying necrotic core . According to histological findings, whereas an intact FC is associated to a low-risk plaque rupture, a thin FC is associated to a mild-risk plaque rupture and a fissured FC, to a high-risk plaque rupture.
Unstable and vulnerable plaques are thus characterized by a thin FC covering a large necrotic core containing macrophages and interstitial collagen. After the FC rupture, the exposure of thrombogenic subendothelial plaque constituents to the luminal blood flow represents a critical event that eventually leads to thromboembolic complications.
IPH is currently recognized as a high risk factor for plaque instability, because it contributes to plaque progression and destabilization [39, 40], causing complications by promoting vulnerability, luminal occlusion or embolic events. Several studies have found a strong association between IPH and cerebrovascular events [41, 42, 43]. Gross and microscopic pathological investigations suggested that IPH occurs more often in symptomatic patients undergoing CEA and that the age of the hematoma correlates with the timing of the symptoms [44, 45]. Histopathological examinations have revealed the association between IPH and the presence of neovessels . Particularly, a study suggested the possible rupture of neovessels as cause of production and expansion of IPH .
The Plaque Composition
Carotid artery plaques are constituted by different components and the relative proportion of these components can vary greatly from one plaque to the other. These differences are important because different types of plaque are associated with different risks of stroke. Ultrasound, and especially CT and MRI, can offer information about the carotid artery plaque composition.
On ultrasonography, the analysis of the echogenicity is the main parameter that reflects the plaque composition. One of the most used method is the Gray-Weale’s classification modified by Geroulakos  that classifies the plaque in five types according to the level of echogenicity: type 1 (anechogenic with echogenic FC); type 2 (predominantly anechogenic but with echogenic areas representing less than 25 % of the plaque); type 3 (predominantly hyperechogenic but with anechogenic areas representing less than 25 % of the plaque); type 4 (echogenic and homogeneous plaque); and type 5 (unclassified plaques reflecting calcified plaques with areas of acoustic shadowing which hide the deeper part of the arterial layers). It was demonstrated that types 1 and 2 are similar to CT fatty plaques, types 3 and 4 as mixed plaques, and type 5 as calcified plaques [61, 62] (Fig. 5).
MRI can depict carotid artery plaque composition but, as described in the previous section, its best potential lies in its ability to identify the presence of haemorrhage within a plaque and to characterize its age . The type of the plaque is associated not only with the potential development of cerebrovascular events but also with the presence of other conditions that affect the brain such as cerebral micro-bleeds and leukoaraiosis [63, 64, 65].
This information also is extremely important for risk assessment of carotid artery stenting (CAS) because some conditions (circumferential calcification or large necrotic cores with thin or ruptured FC) are considered as a counterindication to the CAS procedure. In particular, Kamenskiy et al.  recently found that patients with circumferential, heavily calcified plaques, located in the distal portion of the internal carotid artery are most likely to have poststenting geometric changes and complications, whereas Tsutsumi et al.  found that in those calcified plaques that were treated with CAS there were multiple fragmentations of the calcifications (assessed by MDCT) in 94.4 % of the cases.
The Plaque Volume
The lipid component volume appears to be associated with the presence of plaque ulcerations, which represent a significant risk factor for the development of cerebrovascular events . The plaque composition changes with increasing plaque volume. More specifically, there is an increase in the proportion of lipid and calcification with increasing plaque volume.
The Plaque Neovascularization
Several histopathological studies revealed that the ectopic neovascularization in the intima and media is a hallmark of advanced atherosclerotic lesions . The presence of neovascularization in carotid artery plaques is considered as an element of vulnerability because these microvessels are prone to rupture, and IPH has been shown to accelerate plaque evolution .
MRI also can assess the presence of neovasculature in carotid artery plaques [82, 83, 84, 85]. A recent study by Gaens et al.  showed that dynamic contrast-enhanced MR of carotid atherosclerotic plaques can assess plaque neovasculature and that the Patlak model is well-suited for describing carotid plaque enhancement; the authors found that the K(trans) is an indicator of plaque microvasculature (validated by histology) and that the reproducibility of K(trans) was good.
Contrast Enhancement (US–MRI–CT)
CEUS represents a simple and noninvasive technique for the evaluation of plaque vascularization, allowing for the detection of plaque vasa vasorum that are abundant in vulnerable plaques [86, 87, 88].
Different ultrasound contrast agents are commercially available. They differ basing on their composition (protein, lipid, phospholipid, or sulfur hexafluoride microbubbles), but they have the common characteristic that they resonate when exposed to an ultrasound wave. The enhancement of the arterial lumen allows to assess the degree of stenosis and to evaluate luminal irregularities, dissections, or ulcerations. At the same time, the technique allows direct visualization of the adventitial vasa vasorum and intraplaque angiogenesis. A recent article by Staub et al.  concluded that vulnerable plaques frequently have a greater degree of neovascularization and that the presence of plaque neovessels correlates with lesion severity and with morphologic features of plaque instability. Therefore, contrast-enhanced ultrasound can represent a valuable tool for risk stratification of unstable plaques .
High-Resolution and Contrast-Enhanced Magnetic Resonance Imaging
High-resolution magnetic resonance imaging is a useful noninvasive tool for characterizing atherosclerotic plaque composition and provides excellent images of the arterial wall. The high field strength (1.5–3 T), the high-contrast resolution and the use of dedicated surface radiofrequency coils that increase the signal-to-noise ratio allow to go beyond the assessment of stenosis degree and to depict plaque components (FC, lipidic core, calcification, IPH), Contrast-enhanced magnetic resonance angiography (CE-MRA) has been demonstrated to be a very accurate noninvasive test for the detection of significant (70–99 %) symptomatic carotid artery stenosis . Different contrast agents are currently used to characterize carotid plaque. Gadolinium-chelates contrast agents are most commonly used for MRA examinations; for the assessment of unstable plaques, the vascular enhancement of the carotid plaques themselves has been demonstrated to hallmark the presence of an increased endothelial permeability due to plaque inflammation that facilitates the entry of contrast agents [83, 91, 92, 93, 94, 95].
A study by Kerwin et al. confirmed the usefulness of contrast-enhanced MR imaging in both the depiction of plaque inflammation and the differentiation of the plaque components such as fibrous or necrotic portions. Moreover, they showed that early plaque enhancement is due to the presence of internal neovessels, while late enhancement is related neovasculature supply and endothelial permeability . The correlation between the degree of plaque enhancement and the degree of neovascularization, which is itself linked to the degree of plaque inflammation, also was confirmed at histology in a recent study by Millon et al. .
Finally, small particles-based contrast agents (iron oxide) can be used to evaluate the presence of plaque inflammation because of their ability to enter atherosclerotic plaques with an increased endothelial permeability and accumulate in migrated macrophages . High-risk inflamed plaques may be identified with a focal area of signal loss visualized on MR images, due to contrast accumulation . Moreover, ultrasmall superparamagnetic iron oxide (USPIO)-enhanced MR imaging has been experimentally used as a biomarker for the screening and the assessment of therapeutic response to statins treatment.
Computed Tomography Angiography
The widespread availability of multi-detector-row CT scanners has made CT angiography the most used noninvasive technique to assess carotid arteries after color-duplex ultrasound. The advantages of this technique are several: velocity of execution, large Z-axis coverage, possibility to use several postprocessing techniques, and the high confidence of the clinicians and surgeons with the CT images. The high spatial resolution combined with very short acquisition times make computed tomography angiography (CTA) of the carotid arteries a very useful tool for the assessment of carotid plaque burden.
A meta-analysis conducted by Koelemay et al. reported sensitivity and specificity values for CTA of 97 and 99 %, respectively, in terms of characterizing the degree of carotid stenosis. In particular, CTA was accurate to characterize 70–99 % stenoses and for the diagnosis or exclusion of occlusions . The ability to scan with very thin slices allows for the accurate evaluation of carotid plaques and of possible intimal irregularities or ulcerations. In terms of CT characterization of plaque components, the presence of high-calcified plaques can hamper a correct estimation of the other components (lipidic core and initial signs of inflammation) because of the blurring artifacts. This limit does not exist for soft plaques.
Finally, CTA is particularly useful for the evaluation of carotid artery remodeling (modifications of lumen diameters following the development of a wall plaque) . The main disadvantage of CTA is the radiation dose delivered to the patient. It is important to underline that the radiation dose can significantly change according to the type of the CT scanner used. In particular, there is a difference between the use of the single source CT versus the dual source CT technology. In a recently published paper , the CDTI of single source CT was 12.5 mGy, whereas using dual energy CT system was 10.64 mGy.
Mannelli et al. , in a recently published “ex vivo” study, compared the size of the calcifications in the carotid artery plaques measured on the different keV images to a histological standard and found that calcium area measured on the 80 keV image set was most comparable to the amount of calcium measured on histology. Saba et al.  assessed “in vivo” the effect of the multispectral imaging in terms of carotid artery plaque classification and found that the HU values of carotid artery plaque significantly change according to the selected keV. Results from this study demonstrated that the HU-based plaque type (fatty and mixed) classification can be improved with the use of multienergy imaging.
Clinical Practice and Results from the Scientific Studies
In the past years, several studies have demonstrated that the degree of luminal stenosis represents only one of the parameter that can determine the ischemic stroke and gradually we have evolved to the concept of vulnerable plaque from the concept of risk arising from the degree of stenosis [9, 10, 107]. However, currently there is a discrepancy between these scientific studies and clinical practice; despite of many publications and discussions, plaque imaging techniques are not really the basics of clinical decision making or current guidelines and in the majority of cases decision towards revascularization are not based on plaque morphology but on the degree of stenosis [108, 109, 110]. Evaluation of the role of predictive effects of the previously described imaging parameters are needed and further studies are necessary to incorporate the potential of the advanced imaging techniques in the identification of the vulnerable plaque to selection of the therapeutical approach. Only in this way the identification of the features of plaque vulnerability will have a bigger clinical impact. Another important issue is the economic impact of the application of CTA or MRA in the diagnostic flowcharts. Previous study demonstrated that the cost of digital subtraction angiography is very high and it can be replaced by CTA or MRA ; however, there is no consensus when these techniques should be used and more data are required to define the economic impact of these techniques .
Nowadays, imaging can identify and characterize determinants of carotid atherosclerotic plaque vulnerability and stratify the risk of stroke for patients affected by atherosclerotic disease of carotid arteries. Ultrasound imaging can offer valuable information about the general composition of the plaque and also about the presence and degree of neovascularization within the plaques, when combined with the use of microbubble contrast agents. CT imaging allows assessment of several characteristics of the vulnerable plaques: total volume (and the volume of the subcomponents), classification of the plaque types (fatty, mixed, calcified), analysis of the neovascularization. MRI offers the best level of assessment of carotid artery plaques by analysing features, such as the status of the FC and the presence of IPH. The use of specific contrast agents can target specific cell population, such as macrophages, which are a marker of the inflammatory process within vulnerable plaques. Further studies are necessary to incorporate the potential of the advanced imaging techniques in the identification of the vulnerable plaque to selection of the therapeutical approach.
Conflict of interest
The authors declare that they have no conflict of interest.
- 1.Li R, Duncan BB, Metcalf PA, Crouse JR 3rd, Sharrett AR, Tyroler HA, Barnes R, Heiss G (1994) B-mode-detected carotid artery plaque in a general population. Atherosclerosis Risk in Communities (ARIC) study investigators. Stroke 25(12):2377–2383Google Scholar
- 16.Yoshida K, Sadamasa N, Narumi O, Chin M, Yamagata S, Miyamoto S (2012) Symptomatic low-grade carotid stenosis with intraplaque hemorrhage and expansive arterial remodeling is associated with a high relapse rate refractory to medical treatment. Neurosurgery 70(5):1143–1150PubMedCrossRefGoogle Scholar
- 28.Saba L, Caddeo G, Sanfilippo R, Montisci R, Mallarini G (2007) Efficacy and sensitivity of axial scans and different reconstruction methods in the study of the ulcerated carotid plaque by using multi-detector-row CT angiography. Comparison with surgical results. AJNR Am J Neuroradiol 28:716–723PubMedCrossRefGoogle Scholar
- 35.Demarco JK, Ota H, Underhill HR, Zhu DC, Reeves MJ, Potchen MJ, Majid A, Collar A, Talsma JA, Potru S, Oikawa M, Dong L, Zhao X, Yarnykh VL, Yuan C (2010) MR carotid plaque imaging and contrast-enhanced MR angiography identifies lesions associated with recent ipsilateral thromboembolic symptoms: an in vivo study at 3T. AJNR Am J Neuroradiol 31(8):1395–1402PubMedCrossRefGoogle Scholar
- 39.Takaya N, Yuan C, Chu B, Saam T, Polissar NL, Jarvik GP, Isaac C, McDonough J, Natiello C, Small R, Ferguson MS, Hatsukami TS (2005) Presence of intraplaque hemorrhage stimulates progression of carotid atherosclerotic plaques: a high-resolution magnetic resonance imaging study. Circulation 111(21):2768–2775PubMedCrossRefGoogle Scholar
- 40.Altaf N, Daniels L, Morgan PS, Auer D, MacSweeney ST, Moody AR, Gladman JR (2008) Detection of intraplaque hemorrhage by magnetic resonance imaging in symptomatic patients with mild to moderate carotid stenosis predicts recurrent neurological events. J Vasc Surg 47(2):337–342PubMedCrossRefGoogle Scholar
- 42.Takaya N, Yuan C, Chu B, Saam T, Underhill H, Cai J, Tran N, Polissar NL, Isaac C, Ferguson MS, Garden GA, Cramer SC, Maravilla KR, Hashimoto B, Hatsukami TS (2006) Association between carotid plaque characteristics and subsequent ischemic cerebrovascular events: a prospective assessment with MRI-initial results. Stroke 37(3):818–823PubMedCrossRefGoogle Scholar
- 53.de Weert TT, Ouhlous M, Meijering E, Zondervan PE, Hendriks JM, van Sambeek MR, Dippel DW, van der Lugt A (2006) In vivo characterization and quantification of atherosclerotic carotid plaque components with multidetector computed tomography and histopathological correlation. Arterioscler Thromb Vasc Biol 26(10):2366–2372PubMedCrossRefGoogle Scholar
- 58.Sangiorgi G, Rumberger JA, Severson A (1998) Arterial calcification and not lumen stenosis is highly correlated with atherosclerotic plaque burden in humans: a histologic study of 723 coronary artery segments using nondecalcifying methodology. J Am Coll Cardiol 31:126–133PubMedCrossRefGoogle Scholar
- 76.Jaipersad AS, Shantsila A, Silverman S, Lip GY, Shantsila E (2012) Evaluation of carotid plaque neovascularization using contrast ultrasound. Angiology. doi: 10.1177/0003319712457013
- 83.Lobbes MB, Heeneman S, Passos VL, Welten R, Kwee RM, van der Geest RJ, Wiethoff AJ, Caravan P, Misselwitz B, Daemen MJ, van Engelshoven JM, Leiner T, Kooi ME (2010) Gadofosveset-enhanced magnetic resonance imaging of human carotid atherosclerotic plaques: a proof-of-concept study. Invest Radiol 45(5):275–281PubMedCrossRefGoogle Scholar
- 84.Oppenheim C, Naggara O, Touzé E, Lacour JC, Schmitt E, Bonneville F, Crozier S, Guégan-Massardier E, Gerardin E, Leclerc X, Neau JP, Sirol M, Toussaint JF, Mas JL, Méder JF (2009) High-resolution MR imaging of the cervical arterial wall: what the radiologist needs to know. Radiographics 29(5):1413–1431PubMedCrossRefGoogle Scholar
- 85.Gaens ME, Backes WH, Rozel S, Lipperts M, Sanders SN, Jaspers K, Cleutjens JP, Sluimer JC, Heeneman S, Daemen MJ, Welten RJ, Daemen JW, Wildberger JE, Kwee RM, Kooi ME (2013) Dynamic contrast-enhanced MR imaging of carotid atherosclerotic plaque: model selection, reproducibility, and validation. Radiology 266(1):271–279PubMedCrossRefGoogle Scholar
- 88.Vicenzini E, Giannoni MF, Puccinelli F, Ricciardi MC, Altieri M, Di Piero V, Gossetti B, Valentini FB, Lenzi GL (2007) Detection of carotid adventitial vasa vasorum and plaque vascularization with ultrasound cadence contrast pulse sequencing technique and echo-contrast agent. Stroke 38(10):2841–2843PubMedCrossRefGoogle Scholar
- 89.Staub D, Partovi S, Schinkel AF, Coll B, Uthoff H, Aschwanden M, Jaeger KA, Feinstein SB (2011) Correlation of carotid artery atherosclerotic lesion echogenicity and severity at standard US with intraplaque neovascularization detected at contrast-enhanced US. Radiology 258(2):618–626PubMedCrossRefGoogle Scholar
- 95.Papini GD, Di Leo G, Tritella S, Nano G, Cotticelli B, Clemente C, Tealdi DG, Sardanelli F (2011) Evaluation of inflammatory status of atherosclerotic carotid plaque before thromboendarterectomy using delayed contrast-enhanced subtracted images after magnetic resonance angiography. Eur J Radiol 80(3):e373–e380PubMedCrossRefGoogle Scholar
- 97.Anzidei M, Napoli A, Marincola BC, Kirchin MA, Neira C, Geiger D, Zaccagna F, Catalano C, Passariello R (2009) High-resolution steady state magnetic resonance angiography of the carotid arteries: are intravascular agents necessary? Feasibility and preliminary experience with gadobenate dimeglumine. Invest Radiol 44(12):784–792PubMedCrossRefGoogle Scholar
- 98.Anzidei M, Napoli A, Marincola BC, Nofroni I, Geiger D, Zaccagna F, Catalano C, Passariello R (2009) Gadofosveset-enhanced MR angiography of carotid arteries: does steady-state imaging improve accuracy of first-pass imaging? Comparison with selective digital subtraction angiography. Radiology 251(2):457–466PubMedCrossRefGoogle Scholar
- 100.Trivedi RA, Mallawarachi C, U-King-Im JM, Graves MJ, Horsley J, Goddard MJ, Brown A, Wang L, Kirkpatrick PJ, Brown J, Gillard JH (2006) Identifying inflamed carotid plaques using in vivo USPIO-enhanced MR imaging to label plaque macrophages. Arterioscler Thromb Vasc Biol 26(7):1601–1606PubMedCrossRefGoogle Scholar
- 105.Mannelli L, Mitsumori LM, Ferguson M, Xu D, Chu B, Branch KR, Shuman WP, Yuan C (2013) Changes in measured size of atherosclerotic plaque calcifications in dual-energy CT of ex vivo carotid endarterectomy specimens: effect of monochromatic keV image reconstructions. Eur Radiol 23(2):367–374PubMedCrossRefGoogle Scholar
- 112.Wardlaw JM, Chappell FM, Stevenson M, De Nigris E, Thomas S, Gillard J, Berry E, Young G, Rothwell P, Roditi G, Gough M, Brennan A, Bamford J, Best J (2006) Accurate, practical and cost-effective assessment of carotid stenosis in the UK. Health Technol Assess 10(30):iii–iv, ix–x, 1–182Google Scholar