Abstract
BackgroundCarotid artery stenting (CAS) is a recognized intervention for preventing atherothrombotic cerebral infarction in patients with internal carotid artery stenosis. Although filter protection systems are used to prevent the migration of distal debris during CAS, in combination with manual aspiration and flow reversal systems, their behavior under retrograde blood flow remains poorly understood. This study aimed to evaluate the filter behavior under various flow conditions in CAS.MethodsAn ex vivo silicone tube model was used to simulate the carotid artery environment during CAS. The FilterWire EZ system was used to examine the filter behavior under various flow conditions: antegrade, stagnation, and retrograde. Additionally, the behavior of the simulated debris was analyzed, including particles that matched the filter pore sizes and smaller particles.ResultsThe filter net expanded under antegrade flow, indented during balloon inflation, and collapsed during manual aspiration. The simulated debris captured by the net was released under retrograde flow conditions. When the antegrade flow was restored, debris similar in size to the net was mostly recaptured, but smaller particles passed through.ConclusionThe effectiveness of filter protection in CAS is contingent on blood flow dynamics and procedural techniques used. These findings advocate for flexible, individualized approaches that consider detailed preoperative assessments of the vascular anatomy and blood flow characteristics to enhance the safety of CAS.