Abstract
BACKGROUND AND PURPOSE: Ulceration in carotid plaque is a risk indicator for ischemic stroke. Our aim was to compare plaque ulcer detection by standard TOF and CE-MRA techniques and to identify factors that influence its detection.
MATERIALS AND METHODS: Carotid MR imaging scans were acquired on 2066 participants in the ARIC study. We studied the 600 thickest plaques. TOF-MRA, CE-MRA, and black-blood MR images were analyzed together to define ulcer presence (plaque surface niche ≥2 mm in depth). Sixty ulcerated arteries were detected. These arteries were randomly assigned, along with 40 nonulcerated plaques from the remaining 540, for evaluation of ulcer presence by 2 neuroradiologists. Associations between ulcer detection and ulcer characteristics, including orientation, location, and size, were determined and explored by CFD modeling.
RESULTS: One CE-MRA and 3 TOF-MRAs were noninterpretable and excluded. Of 71 ulcers in 56 arteries, readers detected an average of 39 (55%) on both TOF-MRA and CE-MRA, 26.5 (37.5%) only on CE-MRA, and 1 (1.5%) only on TOF-MRA, missing 4.5 (6%) ulcers by both methods. Ulcer detection by TOF-MRA was associated with its orientation (distally pointing versus perpendicular: OR = 5.57 [95% CI, 1.08–28.65]; proximally pointing versus perpendicular: OR = 0.21 [95% CI, 0.14–0.29]); location relative to point of maximum stenosis (distal versus isolevel: OR = 5.17 [95% CI, 2.10–12.70]); and neck-to-depth ratio (OR = 1.96 [95% CI, 1.11–3.45]) after controlling for stenosis and ulcer volume.
CONCLUSIONS: CE-MRA detects more ulcers than TOF-MRA in carotid plaques. Missed ulcers on TOF-MRA are influenced by ulcer orientation, location relative to point of maximum stenosis, and neck-to-depth ratio.
ABBREVIATIONS:
- ARIC
- Atherosclerosis Risk in Communities
- CE
- contrast-enhanced
- CFD
- computational fluid dynamics
- CI
- confidence interval
- FD
- flow divider
- IMT
- intima-media thickness
- IQ
- image quality
- MIP
- maximum intensity projection
- OR
- odds ratio
- TOF
- time-of-flight
The risk of stroke in patients with carotid atherosclerotic plaque is influenced not only by plaque size and the degree of obstruction but also by the presence of ulceration.1⇓–3 Thrombus can form within an ulcer crater as a result of disturbances of normal flow patterns and can embolize to the brain, leading to an ischemic event.1,4
Although catheter-based angiography historically has been considered the reference standard for carotid artery assessment, it is limited for identifying ulcers.5⇓–7 Noninvasive imaging modalities now offer stenosis measurements with comparable accuracy8⇓⇓–11 and improved ulcer detection.8 CTA provides superior spatial resolution to that achievable by MRA, but the exposure to ionizing radiation and the reduction in diagnostic accuracy due to wall calcification12 has reinforced the appeal of MRA for carotid disease. This appeal has been further supported by the improved accuracy of MRA over CTA and sonography compared with DSA in recent meta-analyses.13,14
Three-dimensional TOF and CE sequences have become standard MRA techniques used for evaluating carotid stenosis, each with specific advantages. TOF-MRA closely approximates catheter-based stenosis measurements15⇓–17 and has the added advantage of not requiring contrast-agent administration, reducing the chance of nephrogenic systemic fibrosis in patients with renal insufficiency. Moreover, TOF-MRA is usually acquired through the carotid bifurcation only and with a higher spatial resolution, as CE-MRA is typically optimized for coverage from the aortic arch to the skull base, and this may enhance the ability of TOF-MRA to detect small ulcers. Despite these merits, TOF-MRA is often inadequate for detecting tandem lesions15,16,18 and is prone to saturation of slowly flowing or recirculating blood protons, resulting in signal loss within a severely compromised lumen or the carotid bulb, respectively.19,20 Recirculating blood proton saturation could also affect the signal within an ulcer crater.
The optimal MRA technique for detecting carotid plaque ulceration has not been established, and its determination was the primary aim of this study. Our focus was on ulcers that can be angiographically detected and our goal was to determine which technique (TOF-MRA or CE-MRA) misses fewer of these ulcers. Because the signal of an ulcer might depend on the hemodynamic pattern of blood flow within the crater (ie, influencing blood proton saturation on TOF-MRA or the mixing with contrast on CE-MRA), factors that might influence these flow patterns, such as ulcer orientation, location, and size, were explored.
Materials and Methods
Subjects
The ARIC Carotid MR Imaging Study enrolled 2066 participants from 4 communities (Forsyth County, North Carolina; Jackson, Mississippi; suburban Minneapolis, Minnesota; and Washington County, Maryland) to investigate carotid atherosclerotic plaque in a community-representative study including both black and white men and women between the ages of 65 and 84 years in 2005 and 2006. These participants were selected from the larger ARIC cohort, originally recruited in 1987, based on carotid IMT measurements from an earlier sonography examination. Recruitment was designed to include approximately 1200 participants with the highest IMTs (at least ≥68th percentile at each of 4 sites) and around 800 participants randomly selected from the remaining cohort (<68th percentile). Details of this study design were previously described.21 Institutional review boards of the 4 sites approved this Health Insurance Portability and Accountability Act–compliant study, and all participants gave written informed consent. Of 2066 cases, 600 cases with the thickest plaques, based on maximum wall thickness values acquired on black-blood MR images, as previously described,21 were selected for ulcer detection in our study (361 [60%] men; 505 [84%] white; mean age, 72 years).
MR Imaging Examination
A standard imaging protocol was implemented on all participants, and all scans were performed on 1.5T scanners (Minneapolis—Symphony Maestro, Siemens, Erlangen, Germany; 3 other sites—Excite platform, GE Medical Systems, Milwaukee, Wisconsin) using bilateral 4-element phased array carotid coils (Machnet, the Netherlands).21
A 3D TOF-MRA was acquired through both carotid bifurcations in the axial plane with the following parameters: TR/TE/flip angle, 25 ms/3.3–4.7 ms/25°; 2 signal averages; acquired matrix, 256 × 256 zero-padded to 512 × 512; FOV, 150 mm × 150 mm; section thickness, 2 mm without overlap; acquisition time, 4–5 minutes.
Two-dimensional black-blood MR images were acquired through the long axes of both carotid bifurcations and used as a scout to orient a stack of 16 parallel axial 2D black-blood MR images through the carotid artery with the thicker wall or plaque (2-mm section thickness, section gap: 0 mm; 3.2 cm coverage; acquired resolution 0.51 × 0.58 × 2 mm3).
A 3D CE-MRA was acquired in the coronal plane after the intravenous injection of 0.1 mmol/kg gadodiamide (Omniscan, GE Healthcare) by power injector with the following parameters at the 3 sites with GE scanner: TR/TE/flip angle, 5.9ms/1.7ms/29°; 0.5 signal average; section thickness, 2 mm with 1-mm overlap; FOV, 200 mm × 200 mm; and acquired matrix, 256 × 160, zero-padded to 512 × 512. The protocol at the sites with Siemens scanner was the same, except for section thickness, 1 mm without overlap; 1 signal average; FOV, 160 mm × 120 mm; and acquired matrix, 320 × 168, zero-padded to 640 × 480. At the Siemens scanner site, the CE-MRA acquisition was timed by bolus tracking, whereas at the GE scanner sites, 3 acquisitions (phases) were acquired, with the first acquired 10 seconds after the start of contrast administration. The phase that demonstrated the best arterial contrast was used for analysis. Acquisition time was approximately 30 seconds for each phase. The axial 2D black-blood MR images were repeated beginning 5 minutes after contrast administration. MIP images were generated for both CE-MRA and TOF-MRA sequences.
Image Analysis
Two experienced analysts (A.P. and M.E.) were trained by a senior neuroradiologist to interpret each MR imaging series and identify ulcers. Analysts were certified based on correctly interpreting a series of challenging test cases. They independently determined ulcer presence by evaluating all available MR images, including TOF-MRA and CE-MRA source images and MIP images, as well as long-axis and pre- and postcontrast short-axis high-resolution black-blood MR images for all 600 cases on the side selected for black-blood MR imaging (ie, the thicker wall/plaque). An ulcer was defined as a niche in the plaque surface measuring ≥2 mm in depth.22⇓–24 CE-MRA and TOF-MRA images were evaluated using short- and long-axis reconstructions of each 3D MRA dataset, along with the MIP images. The black-blood MR images, acquired to achieve a comprehensive characterization of the vessel wall, were used here to identify ulcers in conjunction with the MRA findings.25 These black-blood MR images also ensured that ulcer-like contour irregularities of the carotid artery that actually represented a normal arterial wall with adjacent isolated plaque6,26 were not defined as ulcers. A senior neuroradiologist (B.A.W.) arbitrated any disagreements and a consensus was reached for each case. IQ scores for CE- and TOF-MRA images were assigned using a scale from 0 to 2 (0, poor artery visualization with artifact and/or noise resulting in a noninterpretable image; 1, adequate arterial visualization with artifact and/or noise that does not interfere with interpretation; 2, good arterial visualization with little to no artifact and/or noise resulting in a confident interpretation). Ulcer orientation was categorized into 3 groups: perpendicular, distally pointing, and proximally pointing (Fig 1). In addition, we categorized ulcer location as proximal, isolevel, or distal to the point of maximum stenosis and to the FD. The circumferential location of the ulcer was also recorded (ie, along FD, opposite FD, or on sidewalls). Ulcer cavity and neck dimensions were measured on CE-MRA MIP and source images (Fig 2). An index of ulcer volume was calculated based on the following equation:
Carotid stenosis was measured based on NASCET guidelines.27
Sixty cases of ulcerated carotid arteries were identified. These 60 ulcerated arteries, along with 40 nonulcerated arteries randomly sampled from the remaining 540 cases, were assigned to 2 neuroradiologists (S.K.G. and A.E.N.) for evaluation of ulcer presence. All images were de-identified and assigned in random order. The readers were blinded to the study objectives and evaluated only 1 sequence (CE-MRA or TOF-MRA) at a time without access to other sequences or knowledge of clinical information. MIP and source images were reviewed together for each case and the readers were allowed to generate multiplanar reconstructions of the source images. The readers were told which side to analyze (ie, the thicker side selected for black-blood MRI). CE-MRA and TOF-MRA series for the same case were interpreted in separate sessions, with at least 2 weeks between evaluations to prevent reader recall. Each reader examined all 100 cases and recorded the location of detected ulcers (ie, distance from FD and the position on the axial plane based on a clockwise model). An investigator (M.E.) subsequently matched corresponding ulcers detected by each reader on the CE- and TOF-MRA series using their recorded locations. Images were analyzed using a PACS workstation (Ultravisual, Emageon, Alabama).
Statistical Analysis
A paired t test was used to compare IQ scores between CE- and TOF-MRAs for each case. Percents of ulcers detected by CE- and TOF-MRA techniques were calculated separately for each reader. Intraobserver agreement of the number of ulcers detected for each artery was estimated based on 20 repeat readings for each reader, separated by at least 3 weeks to prevent reader recall, and interobserver agreement was estimated based on all 100 cases. Agreement for CE and TOF-MRA results was estimated separately using weighted κ coefficients. A κ value of <0.4 was characterized as poor agreement; 0.4–0.75 as fair to good; and >0.75 as excellent.28 Logistic regression was used to estimate correlation of TOF-MRA ulcer detection with ulcer orientation, location, volume, neck-to-depth ratio, as well as IQ score and degree of stenosis. We applied robust variance estimates to account for 2 readers' results for each ulcer. Analysis was completed using SPSS 17.0 (SPSS, Chicago, Illinois) and STATA 10.0 (Stata, College Station, Texas).
Computational Fluid Dynamics
To illustrate the effect of ulcer orientation on blood flow patterns within the ulcer, we performed CFD simulations of pulsatile flow in an idealized carotid bifurcation with a 30% eccentric stenosis, as previously described,29 to which we attached representative distally and proximally pointing ellipsoidal ulcers.30 Flow patterns were visualized by randomly seeding 250,000 tracer particles within and away from the ulcer and tracking their evolution over 3 cardiac cycles, using previously reported techniques.31
Results
Study Group Ulcerations
Sixty ulcerated carotid arteries were identified when evaluating all available MR images. MRA images in 4 cases (3 TOF-MRAs; 1 CE-MRA) were noninterpretable (ie, IQ score = 0) due to motion and were excluded, leaving 56 arteries for analysis. Average IQ score was higher for CE-MRA than TOF-MRA (mean ± SD: 1.83 ± 0.40 versus 1.72 ± 0.51, P = .03). Some plaques had multiple ulcers (7 arteries had 2 ulcers per artery, and 4 arteries had 3 ulcers per artery) for a total of 71 ulcers.
Reliability
Interobserver agreement for ulcer detection was excellent (κ = 0.86 [95% CI, 0.77–0.95]) for CE-MRA, and good (κ = 0.72 [95% CI, 0.58–0.86]) for TOF-MRA. Average intraobserver reliability for the 2 readers for both CE- and TOF-MRAs was excellent (κ = 0.91 [95% CI 0.78–1.00], and κ = 0.85 [95% CI, 0.69–1.00], respectively).
Comparison of Ulcer Detection by CE-MRA and TOF-MRA
Each reader detected more ulcers on CE-MRA than TOF-MRA. Table 1 presents ulcer detection results for each MRA technique for individual ulcers and vessels for the 2 readers. As an average, of 71 ulcers, readers detected 55% on both TOF-MRA and CE-MRA, 37.5% only on CE-MRA, and 1.5% only on TOF-MRA, missing 6% of ulcers by both methods. No ulcers were detected on TOF-MRA in an average of 33% of vessels with ulcerated plaques detected on CE-MRA. For the 1 ulcer missed on CE-MRA but detected on TOF-MRA by both readers, the CE-MRA IQ score was 1, because of motion and low arterial contrast, whereas the TOF-MRA IQ was 2, and a carotid body tumor was incidentally noted. Although the tumor did not obscure the ulcer, it was noted to be a distraction. For 11 vessels with multiple ulcers, no ulcer was detected on TOF-MRA in 4 and 5 vessels by reader 1 and reader 2, respectively, whereas all ulcers in these vessels were detected on CE-MRA by both readers. Readers 1 and 2 identified 2 and 1 cases, respectively, of an ulcer-like configuration on the CE-MRA sequence, caused by a plaque indenting the base of the bulb, without evidence for a true ulcerated plaque as confirmed by the black-blood MR imaging. These cases were not identified as ulcerated on the TOF-MRA sequence. For the purpose of comparing TOF- and CE-MRA techniques, these arteries were considered nonulcerated.
Associations between Ulcer Characteristics and its Detection by TOF-MRA
Because only 1 ulcer detected by TOF-MRA was missed on CE-MRA, we restricted our assessment to factors influencing TOF-MRA ulcer detection among ulcers detected by CE-MRA. Table 2 shows the characteristics of 69 ulcers detected by CE-MRA and percents of ulcer detection by TOF-MRA for each characteristic for reader 1. Most ulcers (68%) were perpendicular to the vessel axis, located proximal to the point of maximum stenosis (52%) and on the opposite FD wall (64%). There were no mushroom-shaped ulcers. The 1 ulcer missed on CE-MRA but detected on TOF-MRA was perpendicular to the vessel axis, located isolevel to the point of maximum stenosis and on the opposite FD wall.
Univariate logistic regression demonstrated significant associations between ulcer detection by TOF-MRA and ulcer orientation, location relative to the point of maximum stenosis, neck-to-depth ratio, volume, and degree of stenosis, but not with IQ score, ulcer location relative to FD, and circumferential location. A multivariate logistic regression model for ulcer detection by TOF-MRA, adjusting for all characteristics found to be associated with ulcer detection by the univariate models confirmed the association of ulcer orientation, location relative to the point of maximum stenosis, and neck-to-depth ratio (Table 3).
Ulcer orientation had a strong association with ulcer detection by TOF-MRA. Distally pointing ulcers were positively associated with ulcer detection by TOF-MRA (OR = 5.57, 95% CI = 1.08–28.65; Fig 3A), whereas proximally pointing ulcers were negatively associated (OR = 0.21, 95% CI = 0.14–0.29; Fig 3B). Ulcers isolevel to the point of maximum stenosis were detected less frequently by TOF-MRA than ulcers proximal or distal to the point of maximum stenosis. Ulcers with a higher neck-to-depth ratio were detected more frequently by TOF-MRA.
Computational Fluid Dynamics
As Fig 4 and On-Line Videos 1 and 2 show, most particles leave the ulcer by the end of 1 cardiac cycle; however, some remain and circulate slowly within the ulcer tip. For the distally pointing ulcer, high velocities fill nearly the entire ulcer during systole, whereas for the proximally pointing ulcer, high velocities are more confined to the ulcer opening. The net effect is a larger volume of long-residing particles at the ulcer tip for the latter case.
Discussion
Our results indicate that CE-MRA detects more carotid plaque ulcers than TOF-MRA. Although TOF-MRA can adequately measure carotid stenosis, it detected no ulcers in approximately one-third of ulcerated carotid plaques detected on CE-MRA, even when multiple ulcers were present in a plaque. This highlights the importance of CE-MRA for carotid plaque evaluation, because ulceration is a predictor of impending stroke even after adjusting for stenosis.2,3
To our knowledge, our study is the first population-based study of geometric ulcer characteristics. Our observations extended those previously reported, namely, that perpendicular followed by distally pointing orientations were encountered most frequently, along with a location proximal to the point of maximum stenosis.32⇓⇓–35 We did not encounter mushroom-shaped ulcers, possibly because our study population did not select for advanced disease, as was done in the prior reports.32⇓⇓–35
Our study shows that ulcer detection by TOF-MRA depends on ulcer orientation, location, and neck-to-depth ratio. The influence of these ulcer characteristics on ulcer detection by TOF-MRA can be explained by differences in hemodynamic patterns within the ulcer cavity that affect spin saturation. The general pattern of blood flow in ulcers has been described by Imbesi and Kerber4 for a carotid artery with a perpendicular ulcer. The authors showed that the blood stream partly enters the distal end of the ulcer opening, swirls inside the ulcer pouch opposing the direction of the blood stream in the parent artery, and partly leaves the ulcer, much like flow in the classic driven cavity problem in fluid mechanics.36 In this context, our observation that the neck-to-depth ratio affects ulcer detection on TOF-MRA is consistent with the fact that narrow, deeper cavities tend to harbor larger and slower regions of recirculating flow subject to spin saturation; and also that missed ulcers tend to be isolevel to the stenosis, that is, when the prevailing flow tends to be directed perpendicular to the ulcer opening, as for a driven cavity flow. The fact that our CFD simulations predict a larger volume of longer residing particles for the proximally pointing ulcer case is consistent with the observation that TOF-MRA is more prone to signal loss when the ulcer is pointing away from the blood stream in the parent artery. As suggested by Imbesi and Kerber,4 long-residing platelets in the ulcer cavity more likely aggregate and form thrombus, which can be sucked into the bloodstream based on the Bernoulli effect. Thus, ulcers detected on CE-MRA but missed on TOF-MRA may be at greater risk for clinical events related to thrombus formation.
The limitations of our study include the following: First, histologic validation of ulcer presence was not possible and some ulcers may have been missed, even on CE-MRA imaging. This is particularly true for shallow, intimal ulcerations and for tiny ulcers embedded in plaque surface irregularities.6 This is a consequence of the main objective of this study, which is to analyze ulcers that are angiographically detectable. We could not effectively compare TOF- and CE-MRA techniques using ulcers that can only be detected by specimen analysis. These MRA techniques are also potentially subject to falsely identifying ulcers, as when a segment of normal vessel wall exists between 2 plaques.6,26 We combined high-resolution black-blood MR imaging and MRA techniques (including MIP and source images) to maximize our ability to detect all ulcers25 and to ensure that these ulcer-like appearances were not counted as true ulcers. Furthermore, the emphasis of our study was a comparison of techniques, and we did not attempt to estimate the positive predictive value of either MRA method.
Second, the lower IQ scores observed for TOF-MRA might have interfered with ulcer detection. The lower scores may have been the consequence of the longer acquisition time for TOF-MRA, making it more prone to motion-related artifact compared with the CE-MRA technique. After excluding the noninterpretable cases (IQ score = 0), there was no association between IQ score and ulcer detection by TOF-MRA. Nevertheless, we noticed lower IQ score related to motion artifacts was a possible reason for some missed ulcers on TOF-MRA, rather than the hemodynamic basis described previously.
Conclusions
TOF-MRA misses as many as one-third of carotid plaque ulcers that can be detected by CE-MRA, and these misses are influenced by hemodynamic patterns of blood flow that depend on ulcer orientation (proximally pointing), position relative to narrowing, and geometry (low neck-to-depth ratio). These patterns of flow that lead to saturation of proton spins and signal loss on TOF-MRA might also create an environment conducive to thrombus formation and influence its risk for stroke, though further work is needed to establish an association with this potential consequence.
Acknowledgments
Two of the authors acknowledge the support of a Heart & Stroke Foundation Career Investigator Award (D.A.S.) and Research Fellowship (Y.H.), respectively. The authors thank Emily Wong for guidance in the design of the CFD ulcer models. The authors also thank the staff and participants of the ARIC study for their important contributions.
Footnotes
The Atherosclerosis Risk in Communities Study is carried out as a collaborative study supported by National Heart, Lung, and Blood Institute contracts (HHSN268201100005C, HHSN268201100006C, HHSN268201100007C, HHSN268201100008C, HHSN268201100009C, HHSN268201100010C, HHSN268201100011C, and HHSN268201100012C) with the ARIC carotid MRI examination funded by U01HL075572–01. Two of the authors received the support of a Heart & Stroke Foundation Career Investigator Award (D.A.S.) and Research Fellowship (Y.H.), respectively.
Some of the results of this study previously presented at: 48th Annual Meeting of the American Society of Neuroradiology, May 17, 2010; Boston, Massachusetts.
Indicates open access to non-subscribers at www.ajnr.org
References
- Received October 24, 2011.
- Accepted after revision January 22, 2012.
- © 2013 by American Journal of Neuroradiology