Centre for Applied Biomedical Engineering Research (CABER), Department of Mechanical and Aeronautical Engineering, and Materials and Surface Science Institute, University of Limerick, Ireland.
J Biomech. 2010 May 7;43(7):1408-16. doi: 10.1016/j.jbiomech.2009.09.057. Epub 2010 Feb 12.
In the event of abdominal aortic aneurysm (AAA) rupture, the outcome is often death. This paper aims to experimentally identify the rupture locations of in vitro AAA models and validate these rupture sites using finite element analysis (FEA). Silicone rubber AAA models were manufactured using two different materials (Sylgard 160 and Sylgard 170, Dow Corning) and imaged using computed tomography (CT). Experimental models were inflated until rupture with high speed photography used to capture the site of rupture. 3D reconstructions from CT scans and subsequent FEA of these models enabled the wall stress and wall thickness to be determined for each of the geometries. Experimental models ruptured at regions of inflection, not at regions of maximum diameter. Rupture pressures (mean+/-SD) for the Sylgard 160 and Sylgard 170 models were 650.6+/-195.1mmHg and 410.7+/-159.9mmHg, respectively. Computational models accurately predicted the locations of rupture. Peak wall stress for the Sylgard 160 and Sylgard 170 models was 2.15+/-0.26MPa at an internal pressure of 650mmHg and 1.69+/-0.38MPa at an internal pressure of 410mmHg, respectively. Mean wall thickness of all models was 2.19+/-0.40mm, with a mean wall thickness at the location of rupture of 1.85+/-0.33 and 1.71+/-0.29mm for the Sylgard 160 and Sylgard 170 materials, respectively. Rupture occurred at the location of peak stress in 80% (16/20) of cases and at high stress regions but not peak stress in 10% (2/20) of cases. 10% (2/20) of models had defects in the AAA wall which moved the rupture location away from regions of elevated stress. The results presented may further contribute to the understanding of AAA biomechanics and ultimately AAA rupture prediction.
在腹主动脉瘤(AAA)破裂的情况下,其结果往往是死亡。本文旨在通过实验确定体外 AAA 模型的破裂位置,并使用有限元分析(FEA)验证这些破裂部位。使用两种不同的材料(道康宁的 Sylgard 160 和 Sylgard 170)制造硅橡胶 AAA 模型,并使用计算机断层扫描(CT)对其进行成像。使用高速摄影术使实验模型膨胀直至破裂,以捕获破裂部位。对 CT 扫描的 3D 重建以及随后对这些模型的 FEA 使我们能够确定每个几何形状的壁面应力和壁厚。实验模型在拐点处破裂,而不是在最大直径处破裂。Sylgard 160 和 Sylgard 170 模型的破裂压力(平均值+/-标准差)分别为 650.6+/-195.1mmHg 和 410.7+/-159.9mmHg。计算模型准确地预测了破裂的位置。Sylgard 160 和 Sylgard 170 模型在内部压力为 650mmHg 时的峰值壁面应力分别为 2.15+/-0.26MPa 和 1.69+/-0.38MPa,在内部压力为 410mmHg 时的峰值壁面应力分别为 2.15+/-0.26MPa 和 1.69+/-0.38MPa。所有模型的平均壁厚均为 2.19+/-0.40mm,Sylgard 160 和 Sylgard 170 材料的破裂位置的平均壁厚分别为 1.85+/-0.33mm 和 1.71+/-0.29mm。在 80%(16/20)的情况下,破裂发生在峰值应力部位,而在 10%(2/20)的情况下,破裂发生在高应力部位,但不是峰值应力部位。10%(2/20)的模型在 AAA 壁上存在缺陷,这使破裂位置偏离了升高的应力区域。本研究结果可能进一步有助于理解 AAA 的生物力学特性,并最终有助于预测 AAA 的破裂。
