Novel brain computed tomography perfusion for cerebral malperfusion secondary to acute type A aortic dissection

The purpose of these guidelines is to provide an up-to-date comprehensive set of recommendations for clinicians caring for adult patients with acute arterial ischemic stroke in a single document. The intended audiences are prehospital care providers, physicians, allied health professionals, and hospital administrators. These guidelines supersede the 2013 guidelines and subsequent updates.

We evaluate associations between the severity of magnetic resonance perfusion-weighted imaging abnormalities, as assessed by the hypoperfusion intensity ratio (HIR), on infarct progression and functional outcome in the Diffusion and Perfusion Imaging Evaluation for Understanding Stroke Evolution Study 2 (DEFUSE 2). Diffusion-weighted magnetic resonance imaging and perfusion-weighted imaging lesion volumes were determined with the RAPID software program. HIR was defined as the proportion of TMax >6 s lesion volume with a Tmax >10 s delay and was dichotomized based on its median value (0.4) into low versus high subgroups as well as quartiles. Final infarct volumes were assessed at day 5. Initial infarct growth velocity was calculated as the baseline diffusion-weighted imaging (DWI) lesion volume divided by the delay from symptom onset to baseline magnetic resonance imaging. Total Infarct growth was determined by the difference between final infarct and baseline DWI volumes. Collateral flow was assessed on conventional angiography and dichotomized into good and poor flow. Good functional outcome was defined as modified Rankin Scale ≤2 at 90 days. Ninety-nine patients were included; baseline DWI, perfusion-weighted imaging, and final infarct volumes increased with HIR quartiles (P<0.01). A high HIR predicted poor collaterals with an area under the curve of 0.73. Initial infarct growth velocity and total infarct growth were greater among patients with a high HIR (P<0.001). After adjustment for age, DWI volume, and reperfusion, a low HIR was associated with good functional outcome: odds ratio=4.4 (95% CI, 1.3-14.3); P=0.014. HIR can be easily assessed on automatically processed perfusion maps and predicts the rate of collateral flow, infarct growth, and clinical outcome.

To assess outcomes of endovascular reperfusion followed by delayed open aortic repair for stable patients with acute type A aortic dissection (ATAAD) and mesenteric malperfusion syndrome (MesMPS). Among 602 patients with ATAAD who presented to our center from 1996 to 2017, all 82 (14%) with MesMPS underwent upfront endovascular fenestration/stenting. Primary outcomes were in-hospital mortality and long-term survival. ATAAD patients with no malperfusion syndrome of any organ (n=419) served as controls. In-hospital mortality of all comers with MesMPS was 39%. After endovascular fenestration/stenting, 20 (24%) MesMPS patients died from organ failure and 11 (13%) from aortic rupture before open aortic repair, 47 (58%) underwent aortic repair, and 4 (5%) survived without open repair. No patients died from aortic rupture during the second decade (2008-2017). The significant risk factors for death from organ failure after endovascular reperfusion were acute stroke (odds ratio (OR)= 23 (95% CI: 4, 144), p=0.0008), gross bowel necrosis at laparotomy (OR= 7 (1.4, 34), p=0.016), and serum lactate ≥6 mmol/L (OR= 13.5 (2, 97), p=0.0097). There was no significant difference in operative mortality (2.1% vs. 7.5%; p=0.50) or long-term survival between MesMPS patients who underwent open aortic repair after recovering from MesMPS and patients with no malperfusion syndrome. In ATAAD patients with MesMPS, endovascular fenestration/stenting and delayed open aortic repair achieved favorable short- and long-term outcomes. Surgeons should consider correcting mesenteric malperfusion before undertaking open aortic repair in MesMPS patients, especially those with acute stroke, gross bowel necrosis at laparotomy, or serum lactate ≥6 mmol/L.