Perfusion-Based Selection for Endovascular Reperfusion Therapy in Anterior Circulation Acute Ischemic Stroke

Discussion

In a multicenter study, we observed that patients selected for ERT by perfusion imaging were more than 2-fold more likely to have good functional outcomes compared with NCCT-selected patients, despite an older age and modest delays in time to treatment. These results were independent of other known predictors of good outcome, including stroke severity, comorbidities, IV tPA utilization, and TICI reperfusion score.

Our data are consistent with some previously published work that observed higher rates of good outcome ranging from 41% to 67% by using perfusion selection for ERT compared with historic controls.²⁰ Others have noted that perfusion selection attenuates or negates the influence of time so that good outcomes can be achieved in similar proportions after 8 hours compared with <8 hours by using perfusion imaging.^21,22 However, 2 retrospective prior studies comparing perfusion selection with NCCT selection have failed to show a benefit of one approach over the other.^12,13 Hassan et al¹³ demonstrated equivalent discharge outcomes, symptomatic hemorrhage rates, and mortality rates in a retrospective analysis comparing NCCT- versus CTP-based patient selection. The methodology for qualitative and quantitative penumbral assessment was MTT ≥ 20% of the affected region or a presumed mismatch ratio of >1.2. Sheth et al¹² also performed a multicenter retrospective analysis and found no difference in clinical outcomes with NCCT, CTP, or MR imaging–based selection. However, this study provided no specific parameters used for advanced imaging selection and likely lacked standardized patient-selection approaches in each subgroup. Neither study performed post hoc core infarct/penumbra analyses. Lack of standardized and/or less stringent perfusion imaging criteria may explain their null results compared with our findings. Additionally, Sheth et al¹² noted that CT perfusion or MR imaging selection added approximately a 60-minute delay to treatment. Although we also observed a 40-minute delay with perfusion selection, the potential improved selection and association with better outcomes may justify this approach. It should be acknowledged that perfusion-based selection may result in higher proportions of treated patients with good outcomes, though fewer patients overall may actually receive ERT compared with NCCT-based selection.

Studies of imaging-based selection in acute ischemic stroke have produced mixed results, at least partly due to the variability of techniques, postprocessing software algorithms, and definitions of core infarct and penumbra that parse oligemia from true ischemia.²³ Critics of perfusion-based patient-selection strategies for acute stroke intervention cite the limited MR imaging accessibility; additional time required for imaging, resulting in endovascular treatment delays; the lack of standardized postprocessing perfusion software; failure to quantitatively model the dynamic properties of in vivo cerebral perfusion (ie, contrast delay-dispersion correction and retrograde pial collateral supply); and an inability to differentiate a true penumbra (ischemic tissue destined to infarct without reperfusion) versus false penumbra (oligemic tissue that will survive). Furthermore, a measurement made 1 or 2 hours before reperfusion may not be a reliable indicator of tissue fate; real-time measurement of tissue perfusion at the time of reperfusion therapy is preferred.

Prior clinical trials of perfusion-based selection for intravenous and intra-arterial reperfusion therapies have produced mixed results. In the desmoteplase studies, the phase 3 trial showed no benefit of delayed thrombolysis based on perfusion imaging selection, defined as a mismatch (penumbra-to-infarct) ratio of >1.2, despite promising phase 2 study results.^24⇓–26 However, post hoc analyses suggested that a minimal mismatch volume of 60 mL would have led to a benefit in favor of desmoteplase.²⁷ Other intravenous thrombolytic phase 2 trials confirmed potential benefit in delayed treatment by using MR diffusion–perfusion imaging–based patient selection.^28,29 In the DEFUSE-2 trial, endovascular reperfusion was associated with a 5-fold increase in favorable clinical outcomes among patients with target mismatch (defined as ratio of >1.8), while no benefit was seen among patients without target mismatch. The trial used standardized MR imaging postprocessing software (RAPID; iSchemaView Inc, Palo Alto, California), which allowed uniform definitions of core infarct, severe perfusion abnormalities, and hence possibly a more accurate measurement of penumbra.¹⁶ Our data are consistent with the DEFUSE-2 study, in which large mismatch ratios (median, 5.8 in our study) were also observed. These data suggest that perfusion imaging selection, if optimized with standardized parameters that best define mismatch and true penumbra, may identify patients most likely to benefit while excluding those who may incur harm from reperfusion therapy.

In contrast, the recently reported Mechanical Retrieval and Recanalization of Stroke Clots Using Embolectomy trial found no benefit of ERT over medical treatment, irrespective of a favorable perfusion imaging profile (“penumbral” versus “nonpenumbral” pattern).³⁰ Most interesting, patients with a penumbral pattern were found to have better outcomes and smaller infarct growth, suggesting a protective effect. It is therefore possible that penumbral selection, as in our study, identifies those patients destined for better outcomes irrespective of treatment. The Mechanical Retrieval and Recanalization of Stroke Clots Using Embolectomy trial identified significant delays in randomization, ranging from 5 to 6 hours, suggesting relatively late CTP/MRP acquisitions. Penumbral patterns noted at various time points after stroke onset (early versus late) may also be indicative of differing risk profiles so that early imaging may mark those with a high risk of infarct growth and deterioration, while late imaging may identify those with good collateral flow that protects against infarct growth and deterioration.^31,32 Further work related to imaging techniques with respect to reproducibility, standardized definitions of optimal parameters, and postprocessing methodologies for distinguishing penumbra from infarct core are clearly needed.

Our study has several limitations. First, we did not prospectively adjudicate NCCT or perfusion imaging selection for ERT. While ASPECTS and mismatch criteria have been developed and may have been used at our sites,^11,16 decisions regarding eligibility were determined by the local treating physicians by using differing modalities and software platforms. In addition, CTP and MRP may have differing accuracies for predicting infarct core and penumbra and differing spatial coverage so that CTP may provide only limited coverage²³; however, outcomes among those selected by CT versus MR perfusion were not different in our study. Second, our results are not generalizable to posterior circulation strokes. Besides different natural histories compared with anterior circulation stroke, posterior circulation stroke has challenges in perfusion imaging selection. Only small studies using MRP have been conducted in posterior circulation stroke, and none has clearly demonstrated its utility in selection for ERT.³³ Third, outcomes following ERT are also dependent on time to reperfusion.¹⁰ Capturing reperfusion times is often challenging in clinical practice due to infrequent sequential angiographic runs and the possibility of slow and steady reperfusion or partial followed by complete reperfusion. Fourth, the type of mechanical thrombectomy device was not controlled for in the study, though a minority (15 patients) was treated with the new generation of stent retrievers. Recent advances in retrievable-stent technology may lead to earlier and higher rates of reperfusion with minimal symptomatic hemorrhage.^18,19

Fifth, all data in the registry were entered by local sites without central adjudication and were aggregated post hoc in a de-identified manner. We do not know how many patients were excluded from ERT on the basis of NCCT or perfusion imaging results; therefore, we cannot comment on outcomes in those who did not receive ERT. Grading TICI scores, in particular, can demonstrate significant interobserver variability, depending on whether the primary arterial occlusion was completely or partially recanalized, the presence of distal emboli, and the role of pial collaterals. Grading final reperfusion can also demonstrate site-reported bias in favor of better scores, compared with central adjudication, as demonstrated in the solitaire flow restoration device versus the Merci retriever in patients with acute ischaemic stroke (SWIFT) trial.¹⁹ However, our hospitals have participated in large endovascular clinical trials, and consensus definitions were used to define key variables such as TICI grade and symptomatic hemorrhage. Angiographic collateral grade was also not systematically documented or available on post hoc review. Sixth, bias from the treating physicians may have resulted in use of perfusion selection for specific subgroups of patients, which could account for the difference in outcomes. Seventh, we also did not adjust for site characteristics such as volume of cases per year or operator experience, which may influence outcomes.³⁴ However, site performance as measured by rates of TICI 2b or 3 reperfusion and symptomatic hemorrhage were not different by site. Last, residual or unmeasured confounding could account for some or all of our results.