Perrin David, Badel Pierre, Orgeas Laurent, Geindreau Christian, du Roscoat Sabine Rolland, Albertini Jean-Noël, Avril Stéphane
Ecole Nationale Supérieure des Mines de Saint-Etienne, CIS-EMSE, SAINBIOSE, F-42023 Saint-Etienne, France; CNRS, 3SR Lab, F-38000 Grenoble, France; Univ. Grenoble Alpes, 3SR Lab, F-38000 Grenoble, France; INSERM U1059, SAINBIOSE, F-42023 Saint-Etienne, France; Université de Lyon, F-69000 Lyon, France.
Ecole Nationale Supérieure des Mines de Saint-Etienne, CIS-EMSE, SAINBIOSE, F-42023 Saint-Etienne, France; INSERM U1059, SAINBIOSE, F-42023 Saint-Etienne, France; Université de Lyon, F-69000 Lyon, France.
J Mech Behav Biomed Mater. 2016 Oct;63:86-99. doi: 10.1016/j.jmbbm.2016.06.013. Epub 2016 Jun 17.
The rate of post-operative complications is the main drawback of endovascular repair, a technique used to treat abdominal aortic aneurysms. Complex anatomies, featuring short aortic necks and high vessel tortuosity for instance, have been proved likely prone to these complications. In this context, practitioners could benefit, at the preoperative planning stage, from a tool able to predict the post-operative position of the stent-graft, to validate their stent-graft sizing and anticipate potential complications. In consequence, the aim of this work is to prove the ability of a numerical simulation methodology to reproduce accurately the shapes of stent-grafts, with a challenging design, deployed inside tortuous aortic aneurysms. Stent-graft module samples were scanned by X-ray microtomography and subjected to mechanical tests to generate finite-element models. Two EVAR clinical cases were numerically reproduced by simulating stent-graft models deployment inside the tortuous arterial model generated from patient pre-operative scan. In the same manner, an in vitro stent-graft deployment in a rigid polymer phantom, generated by extracting the arterial geometry from the preoperative scan of a patient, was simulated to assess the influence of biomechanical environment unknowns in the in vivo case. Results were validated by comparing stent positions on simulations and post-operative scans. In all cases, simulation predicted stents deployed locations and shapes with an accuracy of a few millimetres. The good results obtained in the in vitro case validated the ability of the methodology to simulate stent-graft deployment in very tortuous arteries and led to think proper modelling of biomechanical environment could reduce the few local discrepancies found in the in vivo case. In conclusion, this study proved that our methodology can achieve accurate simulation of stent-graft deployed shape even in tortuous patient specific aortic aneurysms and may be potentially helpful to help practitioners plan their intervention.
术后并发症发生率是血管内修复术(一种用于治疗腹主动脉瘤的技术)的主要缺点。例如,具有短主动脉颈和高血管迂曲度等复杂解剖结构已被证明容易出现这些并发症。在这种情况下,从业者在术前规划阶段可以受益于一种能够预测支架移植物术后位置、验证其支架移植物尺寸并预测潜在并发症的工具。因此,这项工作的目的是证明一种数值模拟方法能够准确再现具有挑战性设计的支架移植物在迂曲腹主动脉瘤内展开时的形状。通过X射线显微断层扫描对支架移植物模块样本进行扫描,并进行力学测试以生成有限元模型。通过模拟在从患者术前扫描生成的迂曲动脉模型内展开支架移植物模型,对两例血管内腹主动脉瘤修复(EVAR)临床病例进行了数值再现。同样,通过从患者术前扫描中提取动脉几何形状生成刚性聚合物模型,模拟了体外支架移植物在该模型中的展开,以评估体内情况下生物力学环境未知因素的影响。通过比较模拟结果和术后扫描结果来验证结果。在所有情况下,模拟预测的支架展开位置和形状的精度可达几毫米。在体外情况下获得的良好结果验证了该方法在非常迂曲的动脉中模拟支架移植物展开的能力,并表明对生物力学环境进行适当建模可以减少体内情况下发现的一些局部差异。总之,本研究证明,即使在针对特定患者的迂曲腹主动脉瘤中,我们的方法也能实现对支架移植物展开形状的准确模拟,并且可能有助于从业者规划他们的干预措施。
