Frictional forces in stent retriever procedures: The impact of vessel diameter, angulation, and deployment position.

Surgical neurology international Pub Date : 2024-10-25 eCollection Date: 2024-01-01 DOI:10.25259/SNI_709_2024

Kazuma Tsuto, Masataka Takeuchi, Yu Shimizu, Takashi Matsumoto, Satoshi Iwabuchi

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Abstract

Background: Mechanical thrombectomy has improved the outcome of patients with acute ischemic stroke, but complications such as subarachnoid hemorrhage (SAH) can worsen the prognosis. This study investigates the frictional forces exerted by stent retrievers (SRs) on vessel walls, hypothesizing that these forces contribute to vascular stress and a risk of hemorrhage. We aimed to understand how vessel diameter, curvature, and stent deployment position influence these forces.

Methods: Using a silicone vascular model simulating the middle cerebral artery, we created virtual vessels with diameters of 2.0 mm and 2.5 mm, each with branching angles of 60° and 120°. A Trevo NXT (4 × 28 mm) SR was deployed and retracted through these models, measuring the maximum static frictional force at the moment the SR began to move. The stent deployment position relative to the curvature (straight, distal 1/4, center, and proximal 1/4) was also varied to assess its impact on frictional forces. Each condition was tested 15 times, and the results were statistically analyzed.

Results: The highest frictional force was observed in the 2.0 mm/120° model, followed by the 2.0 mm/60°, 2.5 mm/120°, and 2.5 mm/60° models. Narrower and more sharply curved vessels exhibited significantly higher frictional forces. Friction also increased with more distal stent deployment, particularly in the narrower vessels.

Conclusion: Smaller vessel diameters, greater curvature, and more distal stent deployment positions increase frictional forces during thrombectomy, potentially leading to SAH. These findings highlight the importance of selecting appropriately sized SRs and considering stent deployment positions to minimize vascular stress.

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支架回流手术中的摩擦力：血管直径、角度和部署位置的影响。

背景：机械血栓切除术改善了急性缺血性中风患者的预后，但蛛网膜下腔出血（SAH）等并发症会使预后恶化。本研究调查了支架取栓器（SR）对血管壁产生的摩擦力，假设这些摩擦力会导致血管应力和出血风险。我们旨在了解血管直径、曲率和支架部署位置如何影响这些力：我们使用硅胶血管模型模拟大脑中动脉，创建了直径分别为 2.0 毫米和 2.5 毫米的虚拟血管，每条血管的分支角度分别为 60°和 120°。通过这些模型展开和缩回 Trevo NXT（4 × 28 毫米）SR，测量 SR 开始移动时的最大静摩擦力。此外，还改变了支架相对于弧度的展开位置（直线、远端 1/4、中心和近端 1/4），以评估其对摩擦力的影响。每种情况都测试了 15 次，并对结果进行了统计分析：结果：摩擦力最大的是 2.0 mm/120° 模型，其次是 2.0 mm/60°、2.5 mm/120° 和 2.5 mm/60° 模型。更窄和更弯曲的血管表现出明显更高的摩擦力。摩擦力也随着支架部署越远而增加，特别是在较窄的血管中：结论：血管直径越小、弯曲度越大、支架部署位置越远，血栓切除术中的摩擦力就越大，有可能导致 SAH。这些发现强调了选择尺寸合适的 SR 和考虑支架部署位置以尽量减少血管应力的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Surgical neurology international

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