The p48 Flow Modulation Device with Hydrophilic Polymer Coating (HPC) for the Treatment of Acutely Ruptured Aneurysms: Early Clinical Experience Using Single Antiplatelet Therapy

The p48MW HPC comprises 48 braided drawn solid tubular wires. Each strand is made of platinum-filled nitinol tubing and coated with a recently developed glycan-based multilayer hydrophilic polymer coating (pHPC, phenox). Unlike the p64 flow modulation device (phenox), the p48MW HPC is not mechanically detached. A proximal radio-opaque marker on the insertion wire identifies the point at which the device can still be re-sheathed. There is a central, independently moveable stainless steel wire with an atraumatic distal nitinol wire tip to prevent small distal vessels from rupturing. The device is compatible with 0.021″ inner diameter microcatheters and is currently available with a nominal diameter of 2 mm and 3 mm, designed to treat vessels of between 1.75 and 3 mm diameter, respectively.

We retrospectively reviewed our prospectively maintained database to identify all patients treated with a p48MW HPC under SAPT within 30 days of an aSAH. We also included cases in which FD was performed within 30 days of hemorrhage, but in a separate intervention after the initial procedure. Patients who underwent staggered FD of an aneurysmal remnant after 30 days were, however, excluded.

For each patient, we recorded demographic data, clinical presentation, morphology and location of the ruptured aneurysm, size and location of the implanted p48MW HPC, procedural and general complications, and the clinical and radiological outcomes.

All treatments were performed under general anesthesia using biplane digital subtraction angiography (DSA) systems (Axiom, Siemens, Erlangen, Germany) and using either a 6F or an 8F right femoral artery approach. The treatment strategy used was jointly decided by a senior neurointerventionist and a senior vascular neurosurgeon. Depending on the timing of the procedure, patients received either 1 × 100 mg acetylsalicylic acid (ASA, Aspirin, Bayer Vital, Leverkusen, Germany) or 1 × 10 mg prasugrel (Efient, Daiichi Sankyo, Munich, Germany) PO daily for at least 3 days before treatment, or a loading dose of 1 × 500 mg ASA (Aspirin IV 500 mg, Bayer Vital) IV or 1 × 30 mg prasugrel PO 3 h before the procedure. The effectiveness of the antiplatelet regimen was tested in all cases before treatment using the Multiplate Analyzer (Roche Diagnostics, Mannheim, Germany) and VerifyNow (Accriva, San Diego, CA, USA). The maintenance dose was monitored by repeated testing, starting with standard daily doses of 1 × 500 mg ASA IV or 1 × 10 mg prasugrel PO. Patients were temporarily heparinized during the procedure (typically with a bolus of 3000 IU unfractionated heparin IV). Additionally, all flushing solutions, including the guiding catheters and microcatheters, were heparinized (5000 IU unfractionated heparin/l). If thrombus formation occured during the procedure, a body weight-adapted bolus of 180 mcg/kg eptifibatide IV (Integrilin, GlaxoSmithKline, Munich, Germany) was administered. If there proved to be insufficient platelet inhibition under SAPT (confirmed by daily response testing using Multiplate and VerifyNow) with thrombus formation during the postprocedural period, DAPT was started. Should, however, there have been insufficient inhibition under SAPT without apparent thrombus formation, the maintenance dose was increased, but no DAPT was initiated.

Patency and flow characteristics within the parent vessel were assessed angiographically immediately after the FDs were placed. Follow-up angiographies by DSA combined with clinical evaluation were performed during the first week after treatment and again at 3–6 months. Aneurysm occlusion was graded using the Raymond–Roy classification [6].

SAPT with ASA was used for six patients (75%), while for the remaining two patients, prasugrel was used as SAPT (25%). The maintenance doses were monitored by repeated testing. All but one patient (83.3%) receiving ASA required increased dosages of ASA before and after treatment to achieve sufficient platelet inhibition. The patients who received prasugrel showed only minor variability in their platelet inhibition before and after the procedure.

DAPT was started in the postoperative period in three patients (37.5%), all of them receiving ASA as their SAPT regime. In patient #2, DAPT was started due to the small diameter of the treated vessel (A1/A2) and the presence of some vasospasm, which may have increased the risk of in-stent thrombosis. In patient #5, DAPT was started due to delayed thrombus formation secondary to vasospasm and reduced platelet inhibition under ASA, and in patient #7 due to in-stent thrombosis on day 3 after treatment. No patient under prasugrel had to be switched to DAPT.

Intraprocedural thrombus formation inside or in the vicinity of the FDS was observed in a total of 4 patients (50%). However, in patients #2 and #6, this thrombus formation was probably not directly related to the surface of the implanted device, rather induced by vessel vasospasm and the device incompletely opening, respectively. In patients #1 and #5, thrombus formation was observed at the origin of the left A1 segment and the right posterior-inferior cerebellar artery (PICA), respectively. Since the FDS jailed the origins of both vessels, we assume that the thrombus formation was related to reduced flow in those FDS-covered vessels rather than to the device itself. All thrombi resolved once a bolus of eptifibatide IV had been administered. There were no clinical or radiological sequelae of these thrombus formations. Patient #3 and #7 presented with pontine ischemia after the FDS had been deployed into the BA (25%). In both patients, pontine branches originated adjacent to BA aneurysms and occluded alongside the obliterated aneurysm. No other ischemic lesions directly related to the FDS were observed.

Early angiographic follow-up was performed during the first week after treatment in all patients (median 5 days). It showed complete aneurysm occlusion in three patients (37.5%), reconstruction of the parent vessel with minor perfusion of the aneurysm in three patients (37.5%), and residual aneurysm filling in two patients (25%). At that time, non-occlusive thrombus formation was observed inside the FDS in two patients (patient #1 and #5 (25%)). Patient #1 presented with insufficient platelet function inhibition under ASA, confirmed by Multiplate and VerifyNow. Patient #5 presented with massive cerebral vasospasm of the right V4 segment, which resulted in a functional occlusion of the FDS. Blood flow stagnation, together with an insufficient platelet function inhibition under ASA, resulted in a thrombus formation inside the FDS, which ultimately resolved after the switch to DAPT and aggressive vasospasm therapy. Whether this thrombus formation influenced the clinical outcome of these two patients remains unclear since both were still intubated before and after the DSA. At the least, CT and MRI did not reveal cerebral ischemia as a result of these events. In-stent thrombosis was observed in patient #7 on day 3 after the treatment (12.5%), which was also related to insufficient platelet function inhibition under ASA, confirmed by response tests. The distal part of the BA was retrogradely perfused via the posterior communicating artery (PcomA). Recanalization of the FDS inside the BA was observed after the switch to DAPT plus eptifibatide IV (Fig. 2). Under this medication, the patient presented gastrointestinal bleeding that required embolization. No other major hemorrhagic complications were observed in this series.

No rebleeding from the treated aneurysms occurred. Two patients died due to refractory cerebral vasospasm during the postoperative period (Fig. 3). Midterm angiographic follow-up was available for the remaining six patients at an average of 6 months postoperatively (range 3-9 months). In five patients (83%), the aneurysm was completely occluded. In patient #6, the fusiform aneurysm remained unchanged after 8 months with the implanted p48 HPC following the contour of the fusiform vessel enlargement. The infectious origin of said aneurysm was considered to be a possible explanation for this phenomenon.

All patients available for angiographic follow-up were also clinically evaluated based on mRS. Three patients showed good functional recovery after the SAH with mRS ≤ 2 (50%), and three patients presented at mRS > 2 (50%; one patient with mRS 5, and two patients with mRS 4). Table 2 summarizes the clinical and angiographic follow-up results in this series.

Three aneurysms underwent repeated treatment with further FD stents before discharge (37.5%). Patient #5 and #7 showed reperfusion and enlargement of the previously treated dissecting aneurysms after vessel recanalization following DAPT. Patient #2 needed retreatment as, following the deployment of a FDS in the right A1/A2 segment, the AcomA aneurysm was still being perfused via the left A1 segment. A second FDS was then deployed into the left A1/A2 segment in order to complete the endovascular treatment before discharge. No hemorrhagic or thromboembolic procedural complications were observed during retreatments.

Our study has several inherent limitations, which should be considered when interpreting the results. First, this study was limited by its retrospective design and single-center experience with a small sample, which may limit its external validity. Second, because all the aneurysms included were ruptured and in different locations with differing etiologies, patient selection bias is apparent. Third, because not all patients were treated using the same SAPT, and three patients had to be moved from SAPT onto DAPT, the exact effect of HPC was unclear. Physiological conditions and comorbidities of individual patients were not included in this study. However, what we report here is preliminary data, which may help when dealing with similar patients. Further investigations are necessary.