Intra-Arterial Thrombolysis is Associated with Delayed Reperfusion of Remaining Vessel Occlusions following Incomplete Thrombectomy

Early-versus-Delayed Reperfusion

The full efficacy of IAT evaluated within an extended timeframe from IAT initiation until reperfusion assessment is presently unknown. Investigators of the Prolyse in Acute Cerebral Thromboembolism trial (PROACT I and II) found higher reperfusion rates in the IAT-versus-placebo treatment arm when reperfusion was evaluated 120 minutes after IAT application (thrombolysis in myocardial infarction [TIMI] score 2–3 for PROACT I: 57.7% versus 14.3%, P = .017; and for PROACT II: 66% versus 18%, P < .001).^8,9 The Middle Cerebral Artery Embolism Local Fibrinolytic Intervention Trial (MELT) has also reported high reperfusion results in patients receiving IAT (73.7% of patients had reperfusion of >50% of the affected territory) when evaluated within the 2-hour timeframe.¹⁹ However, the recently completed Chemical Optimization of Cerebral Embolectomy (CHOICE) trial reported no significant improvement in reperfusion rates between patients in the IAT and control groups (8.5% versus 7.7%; risk difference = 0.6%; 95% CI, −9.5%–10.7%).⁷ Disparate findings between CHOICE and other trials might be explained by different timing of when reperfusion was assessed (10 versus 120 minutes, respectively). Multicenter observational registries have also reported improvement in angiographic reperfusion in half of treated patients (116/228, 50.9%) when IAT were administrated;²⁰ however, these reperfusion improvements were not always associated with a change of the TICI score, and results should be interpreted cautiously due to possible indication and operator-rating biases.

To fully understand the efficacy of IAT, one should consider the effects over an extended timeframe from IAT initiation until reperfusion assessment. All these trials have reported only rates of early reperfusion and did not report the delayed effect that IAT might have on reperfusion rates. In this study, receiving IAT has shown an association with DR through both unmatched and matched analyses despite lower raw rates of DR in the IAT group. Preclinical studies have already shown the delayed effects of IA urokinase in MCA occlusions.^21,22 When the pharmacologic effect was evaluated at 24 hours, IA urokinase resulted in higher reperfusion rates and also had an added benefit of preserving the integrity of the blood-brain barrier.²¹ IA urokinase has also been shown to reduce microthrombi in secondary distal occlusions and capillary beds, aiding in the reperfusion of microcirculation within the 24-hour time window.²² Therefore, the full thrombolytic efficiency of IA urokinase might be understood only when observed within an extended time window (ie, 24 hours).

Functional Outcome

The effects of IAT on functional outcome have been reported across the studies. PROACT I failed to show differences in rates of 90-day excellent outcome (mRS 0–1; P = .48), though the number of patients in the treatment and control groups was too small to test for differences (n = 8 and 3, respectively).⁸ While PROACT II reported higher rates of 90-day functional independence in patients receiving IAT (mRS 0–2; OR = 2.1; 95% CI, 1.0–4.4),⁹ the MELT trial could not replicate these results (mRS 0–2 for IAT versus the control group, 49.1% versus 38.6%; P = .34).¹⁹ Different findings in these 2 trials are most likely caused by early termination of the MELT trial and the inability to achieve the prespecifed number of enrolled patients for complete analyses. A meta-analysis of IAT trials showed an association between IAT and increased odds of both excellent (OR = 2.1; 95% CI, 1.3–3.5) and functional independent (OR = 2.1; 95% CI, 1.3–3.1) outcomes.⁶ The authors of the CHOICE trial have reported higher rates of excellent outcome in the treatment-versus-placebo group (mRS 0–1; adjusted risk difference = 18.4%; 95% CI, 0.3%–36.4%).⁷ However, results from multicenter observational registries reported no improvement in functional outcome among patients receiving IAT.^20,23

After adjusting for confounders, we have not observed a significant increase in the rates of functional independence among patients who received IAT, even though point estimates seemed to favor these patients. Administration of additional IAT might promote microvascular reperfusion of capillary beds because persistent occlusions of the microvasculature can be observed despite successful thrombi removal from the main blood vessels. This effect of “open capillaries” might translate into higher rates of functional outcome because the association between microvascular reperfusion and 90-day outcome has already been established.^24,25 The nested substudy of the CHOICE trial showed a lower prevalence of microvascular perfusion abnormalities at 48 hours in patients who received IAT versus placebo (24% versus 58%; P = .03).¹¹ This also translated into improved rates of functional independence among patients without microvascular perfusion abnormalities compared with those who still had them (mRS 0–2, 100% versus 67%; P = .004).¹¹ Areas with reperfused principal blood vessels that still experience microvascular occlusions (ie, the no-reflow phenomenon) may be salvageable if microvascular reperfusion is established in a timely manner.

Previous studies have reported conflicting findings between atrial fibrillation and DR.^13,26 Atrial fibrillation might represent a surrogate for another factor that might increase DR rates (eg, anticoagulants); however, these factors were already taken into account in the initial and IPTW analysis. Compared with other stroke etiologies, cardioembolic stroke appears to be more susceptible to IAT treatment;²⁷ hence, it is possible that cardioembolic origin may be the cause of increased DR rates rather than atrial fibrillation. Presently, we are not able to draw any definitive conclusions because this study design is insufficient to test this association and evidence in available literature is modest.

Is There a Place for IAT?

IAT have already been suggested as an adjunctive therapy for patients with incomplete reperfusion (eTICI <3)^3⇓-5 because IAT are usually considered for secondary distal occlusions, which are not amendable by MT. Other therapeutic options (eg, antiplatelets, secondary MT) have also been proposed for this scenario,^28,29 but they all require a careful application and selection of patient subgroups who would be most likely to benefit. One of the safety concerns when administrating IAT is the occurrence of sICH.^3⇓-5 PROACT I reported comparable sICH rates in the treatment and control arms (15.4% versus 7.1%, P > .1).⁸ Conversely, PROACT II reported higher 24-hour hemorrhage rates in the intervention group compared with the control group (35% versus 13%, P = .003).⁹ However, this difference was not significant over time (on 10-day follow-up: 68% versus 57%, P = .23). MELT also reported no difference in sICH rates between patients with and without IAT (9% versus 2%, P = .21).¹⁹ Investigators of the CHOICE trial reported no sICH rates in their treatment group (IAT versus placebo: 0% versus 3.8%; risk difference = −3.8; 95% CI, −13.2%–2.5%).⁷ A recently conducted meta-analysis showed that receiving IAT did not increase sICH rates (OR = 0.8; 95% CI, 0.6–1.3) and IAT had safety and efficacy comparable with those of intravenous thrombolysis.³⁰ Here we also report comparable sICH rates between patients with and without IAT. Because the relationship between IAT and sICH has already been reported across several studies, we aimed to disentangle the association between IAT and the presence of new infarcts on 24-hour follow-up imaging. Present data show a minimal likelihood of new infarcts in residually hypoperfused territory after MT among patients who receive additional IAT. These results are corroborated by the CHOICE trial substudy, which showed that infarct expansion was less likely to occur in patients receiving IAT compared with a placebo (35% versus 74%, P = .02).¹¹

There might be several reasons for consistent findings on safety outcomes across this and previous studies on IAT. First, even minimal improvements in the TICI score produced by IAT are associated with reduced sICH rates.³¹ Second, IA urokinase shows a neuroprotective effect on injured neurons and promotes synaptic recovery in the ischemic area.^32,33 Third, IAT might be able to improve microvascular reperfusion by dissolution of the microthrombi, which persist in the capillary beds and are not directly targeted during the macrovascular reperfusion approach.²² This concept is further mitigated by the idea that not all areas of tissue injury are permanently lost to ischemia and IAT might help provide a more comprehensive treatment approach in patients with incomplete reperfusion.³⁴

Limitations

The design of this single-center retrospective study limits the generalizability of the present study results. IA urokinase was administered at the discretion of the treating neurointervnetionalist, prompting inherent selection bias. Even though steps have been taken to ensure minimal bias of unmeasured confounders, propensity score-matching can be used to balance out only those confounders included in estimating the propensity score and cannot overcome any bias caused by confounders that were not observed. The association between IAT and DR should be interpreted cautiously, because part of the DR rates could be partially attributed to early reperfusion rates, which have been shown to occur occasionally.⁵ However, it would be difficult to evaluate early reperfusion rates in patients without IAT because there are usually no control angiography runs performed 20 minutes after the end of the intervention in this patient subgroup. Therefore, DR was chosen as the primary study outcome because patients both with and without additional IAT would have an imaging end point at 24 hours per standard protocol. Last, this study was not powered to show the true effects of IA urokinase on imaging and clinical outcomes; therefore, all presented results should be interpreted carefully.