Aneurysm dome and vessel pressure measurements with coiling, stent assisted coiling and flow diversion

被引:1
作者
Becker, Timothy A. [1 ]
Lewis, Kailey L. [1 ]
Berns, Holly F. [1 ]
Robertson, Sophia E. [1 ]
Clark, Wyatt E. [1 ]
Wells, Jesse C. [1 ]
Alnajrani, Mohammed K. [1 ]
Rapoport, Christopher [1 ]
Barhouse, Patrick [2 ]
Ramirez-Velandia, Felipe [2 ]
Filo, Jean [2 ]
Young, Michael [2 ]
Muram, Sandeep [2 ]
Granstein, Justin H. [2 ]
Ogilvy, Christopher S. [2 ]
机构
[1] No Arizona Univ, Mech Engn Dept, Flagstaff, AZ USA
[2] Harvard Med Sch, Beth Israel Deaconess Med Ctr, Div Neurosurg, 110 Francis St, Boston, MA 02215 USA
关键词
Intracranial aneurysm; Flow diversion; Coiling; Stent; Pressure; Flow; Occlusion; PIPELINE EMBOLIZATION DEVICE; ENDOVASCULAR TREATMENT; HEMODYNAMICS; RUPTURE; DIVERTORS;
D O I
10.1007/s00701-024-06392-5
中图分类号
R74 [神经病学与精神病学];
学科分类号
摘要
BackgroundVariability in long-term endovascular treatment outcomes for intracranial aneurysms has prompted questions regarding the effects of these treatments on aneurysm hemodynamics. Endovascular techniques disrupt aneurysmal blood flow and shear, but their influence on intra-aneurysmal pressure remains unclear. A better understanding of aneurysm pressure effects may aid in predicting outcomes and guiding treatment decisions. MethodsMedium and large aneurysm models with intramural pressure taps on the dome and parent artery were designed and 3D-printed with vessel-like physical properties from UV-cured materials. The models were connected to a comprehensive flow system consisting of a pulsatile pump and a viscosity-matched blood analog. The system provided physiological pressure and flow control. Real-time pressures were recorded in the aneurysm dome and parent artery during initial placement of coils, stents, flow diverters, and temporary balloons under simulated surgical conditions. Coiling, stent-assisted coiling, and flow diverter placement were performed in both aneurysm sizes. Temporary balloon placement was performed in a large aneurysm model. ResultsCoiling resulted in 24-30% packing density and diminished intra-aneurysmal flow. Flow diverter placement reduced intra-aneurysmal flow with near complete flow interruption after placement of three consecutive devices across the aneurysm neck. Compared to untreated controls, real-time pressure measurements during coiling and flow diversion showed minimal changes (< 5%) in intra-aneurysmal pressures. Temporary balloon occlusion blocked the parent artery, increasing the pressure proximal to the site of occlusion (by 9%), and reducing the pressure distally (by 14%). This maneuver also dampened intra-aneurysmal pressure to the average distal vessel pressure measurement. Positive control aneurysm models were 3D-printed with a sealed, "healed" neck. These controls verified a sealed neck eliminates intra-aneurysmal pressure. ConclusionFindings quantified minimal changes in intra-aneurysmal pressure during and immediately post-coiling and flow diversion. Intra-aneurysmal flow disruption alone has negligible impact on intra-aneurysmal pressures.
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