SWI Susceptibility Vessel Sign in Patients Undergoing Mechanical Thrombectomy for Acute Ischemic Stroke

DISCUSSION

The main findings of this study are the following: The SVS was present in 87.5% (n = 505) of patients treated with MT for intracranial vessel occlusion and was associated with tandem occlusion as well as successful reperfusion. It was independently associated with functional independence and lower mortality rates 90 days after treatment, even after adjusting for successful reperfusion and showed no association with the number of passes performed during MT, the first-pass reperfusion, or the peri- and postinterventional complication rate.

While earlier studies included only a small number of patients,^2,3,8,9,18 more recent ones have examined the SVS in larger study populations.^10⇓-12 However, because several important questions remain, larger studies are required.¹²

Early publications reported an overall SVS prevalence of ∼ 50%^2,3,8 in patients with AIS, whereas more recent studies have indicated that the prevalence is around 70%.^{9⇓⇓-12,18} Our findings suggest that the prevalence may be even higher. There are several possible explanations for these differences: 1) Sample size among the studies examining SVS varied widely, and small test populations may be prone to statistical inaccuracies that limit validity.^11,12,23 2) The eligibility criteria for MR imaging may differ between institutions and hospitals, leading to selection bias. For instance, whereas some hospitals scan patients regardless of special monitoring, others prefer CT when such monitoring is required. However, the SVS distribution may be different in patients whose condition is critical. 3) We only included patients who had undergone MT; consequently, patients who showed spontaneous reperfusion or had sufficient reperfusion after IV thrombolysis were excluded. Despite some evidence to the contrary,^2,3 most studies suggested that SVS+ intracranial vessel occlusions (particularly in the ICA and MCA) are less amenable to IV thrombolysis.^8,24,25 Therefore, it is possible that the overall prevalence is lower if MR imaging is always performed before IV thrombolysis. 4) The comparability of SVS studies is often limited owing to differing inclusion criteria (eg, ICA/M1 occlusions only⁸ versus other occlusion patterns³). 5) Not all studies adopted the same definition of SVS. Whereas some defined it as a signal loss within the margins of an acutely occluded vessel,⁹ others considered the SVS to be present only if the diameter of the signal loss exceeded that of the contralateral vessel.³ 6) The sensitivity for SVS may differ depending on the sequence (T2* gradient recalled-echo versus SWI⁴) and the particular MR imaging scanner used (ie, its field strength and manufacturer). The slightly longer acquisition time for SWI compared with T2* gradient recalled-echo sequences might be justified by the higher spatial resolution of SWI, which provides better visualization of blood-degradation products in distal or small thrombi and has proved to increase SVS sensitivity.⁴ 7) Indications for MT and access to MR imaging have evolved considerably since the SVS was first reported in 2000.¹ Thus, study populations may differ significantly between current and earlier studies.

MT is more effective with erythrocyte-rich than with fibrin-rich thrombi.^14,26,27 Because erythrocyte-rich clots are more likely to result in an SVS+ intracranial vessel occlusion,⁵ SVS may also predict successful reperfusion after MT. If so, it could function as a noninvasive surrogate marker for thrombus composition. Although many studies have addressed this question, only one found an association between the SVS status and reperfusion success after MT.^{9⇓⇓-12,18} Other than the present study, Darcourt et al^11,17 were the only investigators to report a significant relationship between SVS+ intracranial vessel occlusions and successful reperfusion after MT. This report raises the question of why earlier studies found no association. Some of the previously mentioned factors (ie, differing SVS definitions and variations in the sensitivity of SVS detection) may play a role. In addition, Bourcier et al¹⁰ have suggested that first-line MT techniques may affect reperfusion success in AIS patients with SVS. This hypothesis is currently being investigated prospectively (adaptatiVe Endovascular Strategy to the CloT MRI in Large Intracranial Vessel Occlusion [VECTOR] trial; ClinicalTrials.gov Identifier: NCT04139486). Future studies could also investigate whether certain stent-based retrieval techniques are superior to others in terms of reperfusion and/or peri- and postinterventional complication rates. Although our observations suggest that SVS+ thrombi are easier to retrieve via MT than SVS– clots, most data so far suggest that they are less amenable to intravenous thrombolysis. Future studies may examine the risks and benefits of bridging therapy in patients with AIS, depending on the SVS status.

Few data are available on the association of SVS status with clinical outcome after MT. Bourcier et al¹⁸ reported lower NIHSS scores 24 hours after treatment and lower mRS scores 90 days after treatment in SVS+ patients but were not able to confirm the finding in a later study with a larger study population.¹⁰ Darcourt et al¹¹ reported that SVS+ intracranial vessel occlusions were associated with early neurologic recovery. To our knowledge, no other studies have examined clinical outcome in relation to the SVS after thrombectomy. Our data show superior early neurologic recovery when the SVS was present. Furthermore, SVS+ was associated with better functional outcome and survival 90 days after treatment. Because these findings did not change after factoring in reperfusion success, other factors must have contributed to cause worse outcomes in patients in whom the SVS was absent. We hypothesized that atypical thrombi (septic²⁸ or neoplastic^29,30), which are likely to contain few erythrocytes³¹ and develop after a preceding illness, could be part of the explanation. However, in an additional sensitivity analysis, clinical outcome remained worse for the SVS–group when patients with prestroke dependency (mRS > 2) were excluded.

Taking into account that SVS–was also associated with the diagnosis of diabetes mellitus before stroke, further studies on the overall health of patients with SVS–intracranial vessel occlusions are needed to identify underlying, non-stroke-related diseases that may affect thrombus composition³² and could explain prestroke dependency, worse outcome, and/or higher mortality rates. According to our data, the occlusion site, for which we adjusted in all our statistical analyses, did not influence reperfusion success or clinical outcome. However, Aoki et al²³ have suggested differences in outcome for the proximal-versus-distal M1 SVS. Further studies are needed to determine whether the conclusions drawn about SVS as a potential imaging biomarker depend on the affected vessel segment and/or circulation (ie, anterior versus posterior).

The number of passes performed during MT is a good indicator of the difficulty of clot removal. Although Bourcier et al¹⁰ provided data on how often >2 passes were performed, none of the other studies examining the association between SVS status and reperfusion after MT have addressed this question.^9,11,12,18 Our data suggest that there is no difference between patients with SVS+ and SVS– in this regard. However, the number of passes performed is at the discretion of the neurointerventionalist in charge and may vary depending on his or her experience and the applicable standards as well as clinical and environmental factors. Although all MTs evaluated in this study were performed by skilled experts, comparability with future studies from different institutions might be limited as a consequence. Further research is necessary to establish reliable guidelines on appropriate MT strategies and the safe number of passes, depending on clinical aspects and imaging characteristics of the occlusive clot.

We hypothesized that intracranial vessel occlusions caused by thromboembolic incidents originating from arteriosclerotic plaques or dissections of the carotid arteries tend to contain a higher number of trapped erythrocytes with deoxygenated hemoglobin (deoxyhemoglobin, intracellular methemoglobin, or hemosiderin) and, thus, are more likely to be SVS+. Our data support that assumption; 96.0% of patients with severe stenosis or dissection of the carotid arteries had an SVS+ intracranial vessel occlusion. However, we found no association between SVS status and stroke subtypes according to the TOAST classification. Although there are some data indicating that SVS+ is associated with a cardioembolic stroke cause,^3,9 an equal number of studies have found no association between SVS status and stroke subtype whatsoever.^8,10 Some contraindications to MR imaging (pacemakers, implantable cardioverter-defibrillators, and other metal implants) may have altered the distribution of stroke subtypes in our patient cohort because patients with certain pre-existing medical conditions (eg, heart disease) could have been excluded disproportionately. Advances in the development and increasing use of MR imaging–compatible medical devices could allow the inclusion of those patients in future studies. The initial SVS status of intracranial vessel occlusions that resolved without MT may have some diagnostic value with regard to etiology.^3,9 Further research on how spontaneous reperfusion and the efficiency of IV thrombolysis relate to SVS status is required before the potential of SVS as an imaging biomarker for stroke subtype can be evaluated reliably.