Usefulness of Vessel Wall MR Imaging for Follow-Up after Stent-Assisted Coil Embolization of Intracranial Aneurysms

Discussion

An intracranial stent is a powerful tool for the endovascular treatment of wide-neck and fusiform aneurysms. However, stent-related complications can cause permanent neurologic complications. Identifying these complications is important for patient diagnosis, management, and prognosis. Although DSA is standard for the follow-up of coiled aneurysms, it is invasive and exposes patients to procedure-related complications, such as cerebral thromboembolism, contrast nephrotoxicity, and radiation.¹³ Thus, follow-up imaging after endovascular treatment is vital. We evaluated the usefulness of VWMRI after stent-assisted coil embolization of intracranial aneurysms. The primary finding of our study was that VWMRI could reliably identify in-stent complications.

First, we evaluated the relative SI of the stented parent arteries on VWMRI after performing stent-assisted coiling with 2 types of intracranial nitinol stents: Neuroform and Solitaire. The signal intensity of the stented artery was different according to stent type. The relative SI for stented arteries fitted with Neuroform stents was higher than that for the stented arteries fitted with Solitaire stents in our VWMRI study. These findings are consistent with an in vivo study that used a silicone tube to reveal that the mean relative in-stent signal for Neuroform stents was higher than that for the Solitaire stents.¹⁴ The extent of stent-induced signal loss on TOF-MRA has been shown to depend on the thickness of the strut and cell design.¹⁴ The Neuroform stent has an open-cell design and a strut thickness of 65 μm, while the Solitaire stent has a closed cell design and a thickness of 60 μm. Open-cell-design stents have been shown to have lower susceptibility to artifacts compared with closed-cell stents.¹⁴ Moreover, the partially overlapping strut in the Solitaire stent may cause more in-stent signal reduction than in Neuroform stents.

Second, we evaluated the image quality of the stented artery on VWMRI versus TOF-MRA. An intracranial stent can compromise the evaluation of the patency of the vessel on TOF-MRA.¹⁵ Contrast administration can improve vessel lumen visualization.^16,17 Lövblad et al¹⁶ assessed 19 patients with stent-assisted coil embolization using noncontrast TOF-MRA and contrast-enhanced TOF-MRA with 1.5T MR imaging; the contrast administration allowed better visualization of the vessel lumen in the cases that used nitinol stents. Furthermore, the in-stent signal loss was present in all TOF-MRA cases except for contrast-enhanced MRA images. Thamburaj et al¹⁷ assessed 42 patients with stent-assisted coiling and found that contrast-enhanced MRA showed a tendency to demonstrate superior in-stent flow, smoother margins, and minimal-to-no stenosis relative to noncontrast TOF-MRA. However, although complications of contrast agent administration for contrast-enhanced MRA are rare, contrast dye can cause severe allergic reactions and adverse effects. To avoid administration of contrast, we compared VWMRI with TOF-MRA: VWMRI provided better image quality compared with TOF-MRA. The latter method is based on a gradient-echo sequence. Image artifacts due to metal are caused by inhomogeneity in the static magnetic field, and gradient-echo-based sequences are therefore more prone to these artifacts. In contrast, VWMRI is based on a spin-echo sequence, and its use of 3D techniques allows very thin slices; compared with thin 2D slices, susceptibility artifacts are reduced because of the (fast) spin-echo technique.⁹ In contrast to cases in which Neuroform stents were used, neither TOF-MRA nor VWMRI could evaluate the segment near the proximal marker of Solitaire stents. This issue is because the relatively thick, proximal marker near the detachment zone of the Solitaire stent caused complete signal loss of the lumen due to the susceptibility artifacts. However, when the proximal marker was excluded, the image quality of the stented artery on VWMRI was superior to that of TOF-MRA. Agid et al¹⁸ reported a “marker band effect” appearing in arteries ≤2 mm in diameter. The markers of Neuroform stents are made of platinum, which creates strong magnetic susceptibility artifacts. We observed this effect on TOF-MRA in cases in which the Neuroform stent was used in the middle cerebral or posterior cerebral artery. However, this phenomenon did not occur on VWMRI.

Third, we compared VWMRI and TOF-MRA with DSA to evaluate the status of the stented parent artery. Several studies found that MRA with or without contrast material does not seem to provide an effective alternative to DSA for assessing parent artery patency.^{18⇓⇓–21} In a direct comparison between contrast-enhanced MRA and DSA in 27 patients with 28 aneurysms, Agid et al¹⁸ reported 6 cases of false stenosis and 2 of exaggerated stenosis on contrast-enhanced MRA, suggesting that the contrast-enhanced MRA did not depict the true status of the artery. Marciano et al¹⁹ compared TOF-MRA and contrast-enhanced MRA with DSA in 33 patients with 35 aneurysms treated by stent-assisted coiling. The intermodality agreement was poor for 3D TOF-MRA (κ = 0.12) and null for contrast-enhanced MRA (κ = −0.01). TOF-MRA (κ = 0.05) and contrast-enhanced MRA (κ = −0.04) were not able to detect pathologic vessels better than DSA: No difference in accuracy was found (P = .68). Recently, Akkaya et al²⁰ evaluated the usefulness of contrast-enhanced MRA and TOF-MRA in 24 aneurysms treated with low-profile stent-assisted coiling. Although interobserver agreement was substantial in both TOF-MRA (κ = 0.71, P < .001) and contrast-enhanced MRA (κ = 0.64, P = .001), intermodality agreement values of TOF-MRA and contrast-enhanced MRA with DSA were insignificant in terms of stent patency (κ = 0.065, P = .27) and contrast-enhanced MRA (κ = 0.158, P = .15). Choi et al²¹ compared 4D-MRA and 3D TOF-MRA in a group of 26 patients with aneurysms treated with stents. Although the visualization of the stented arteries on 4D-MRA was significantly superior to that on 3D TOF-MRA (P < .001), the investigators doubted whether the degree of in-stent restenosis was accurately measured by 4D-MRA. The ability of 4D-MRA to evaluate in-stent stenosis thus remains undetermined.

Recent studies have demonstrated that Silent MRA (Discovery MR750w; GE Healthcare) might be useful for follow-up imaging after stent-assisted coil embolization.^22,23 In Silent MRA, an ultrashort TE can minimize the phase dispersion of the labeled blood flow signal in the voxel and decrease magnetic-susceptibility artifacts; accordingly, the artifacts from stents or coils are theoretically decreased.²³ Thus, Silent MRA could improve visualization of the stent without contrast administration more clearly than could 3D TOF-MRA.^22,23 However, in Silent MRA, the angiographic image is obtained by subtraction of images scanned before and after labeling. Thus, static tissue such as a thrombus cannot be detected in Silent MRA.²²

In contrast to previous studies that found that MRA techniques were unable to provide a precise evaluation of the stent lumen, our study showed that diagnostic accuracy and the concordance rate between VWMRI and DSA were excellent. VWMRI is helpful in identifying the morphology of intracranial vessels.¹⁵ The present study found that VWMRI was more accurate than TOF-MRA for evaluating the status of the stented parent artery. VWMRI assisted the identification of 3 cases of stenosis and 1 of thrombosis, and its images demonstrated features similar to those shown by DSA.

In our preliminary study, VWMRI did not appear to be useful for evaluating aneurysm stability. We observed that in most cases, the SI of coiled aneurysms on VWMRI was heterogeneous regardless of follow-up duration. Thus, completeness of the coil embolization was overestimated by VWMRI. Various factors such as thrombus organization, fibrosis, and coil-related low SI seem to contribute to heterogeneous SI in the coiled aneurysm. TOF-MRA (particularly with contrast) is good at detecting residual flow and aneurysm recurrence. It would seem that the techniques could be complementary.

The in-stent complication rates in our study were high. We observed that 3 of 4 patients were asymptomatic at follow-up. When a follow-up was performed with only TOF-MRA, DSA was recommended in cases of suspected abnormal findings with associated symptoms. In asymptomatic cases, follow-up was recommended but was often rejected by patients. However, after we used VWMRI, a subsequent DSA test was highly recommended and consequently less often rejected by patients. We speculate that this bias could be attributed to the high incidence of complications.

Asymptomatic in-stent stenosis can change into symptomatic stenosis, or spontaneous resolution of stenosis can occur.²⁴ These events have important clinical implications for the continuation of dual-antiplatelet medication, close observation of neurologic symptoms, and follow-up. For clinical purposes, if MRA with or without contrast material depicts in-stent stenosis or stent occlusion, DSA should be performed to rule out in-stent stenosis or stent occlusion due to false-positive results. Our findings indicate that VWMRI provides a clear depiction of the patency of the parent artery. Accordingly, it is possible to avoid performing DSA in a group of patients in whom there are no particular clinical concerns for stent stenosis/occlusion. In practice, we believe that noninvasive imaging techniques such as VWMRI could be used more frequently than invasive conventional angiography as a follow-up technique.

This retrospective study has several limitations. First, follow-up MR imaging and DSA evaluations were not performed on the same day in most cases. Therefore, these 2 modalities might not reflect the exact same conditions in terms of the state of aneurysms and stented parent arteries. Second, intracranial stents were limited to the Neuroform and Solitaire varieties. Multiple flow diverters or flow-disruption devices are currently available for the treatment of cerebral aneurysms. Several series have reported the usefulness of MRA with contrast material in the follow-up of flow diverters or flow-disruption devices.^25,26 These studies showed that contrast-enhanced MRA yielded better accuracy than TOF-MRA for the status of the parent artery. However, intraluminal evaluation remains difficult due to artifacts in MRA, regardless of the sequence used. This difficulty may be explained by the difference in composition but also porosity, metal coverage, and pore density between stents and flow diverters.²⁵ The usefulness of VWMRI for variable flow diverters or flow-disruption devices should be determined in future studies.

Third, the goal of VWMRI is to reduce the intraluminal signal to zero. Intraluminal SI is not always suppressed fully on VWMRI. Visually, intraluminal SI appeared to be dark in our study. However, intraluminal signals were not zero. Thrombus was assumed if visual assessment revealed higher SI than intraluminal SI. However, there are limitations to visual evaluation when blood suppression is less effective in the presence of slow or complex flow. Novel blood-suppression techniques, including the Delay Alternating with Nutation for Tailored Excitation, can be used to reduce artifacts.²⁷

Fourth, there are limitations concerning the TOF acquisition techniques. The SNR in the stent can be improved by a higher flip angle on the TOF technique.¹⁴ However, we did not use these techniques to improve image acquisition. With the optimization of MR imaging parameters of TOF-MRA according to the various intracranial stents, the luminal visualization of stents could be improved. We performed multislab TOF-MRA with multiple overlapping thin-slab acquisitions. The slab boundaries typically show some artifacts and intensity variations, even if acquired with a generous slab overlap. In our study, the slab artifacts did not significantly affect the reader's interpretation of the image quality. However, the slab boundary artifacts may reduce image quality if the stent is located directly in a slab boundary zone. The single-slab or sliding interleaved projection reconstruction technique can be used to reduce slab boundary artifacts over the conventional TOF technique.²⁸