分层主动脉弓模型内的流固相互作用。
Fluid-structure interaction within a layered aortic arch model.
作者信息
Gao Feng, Guo Zhihong, Sakamoto Makoto, Matsuzawa Teruo
机构信息
Graduate School of Information Science, Japan Advanced Institute of Science and Technology, Nomi, Ishikawa 923-1292, Japan.
出版信息
J Biol Phys. 2006 Nov;32(5):435-54. doi: 10.1007/s10867-006-9027-7. Epub 2006 Dec 13.
Abstract
The response of wall stress to the elasticity of each layer in the aorta wall was investigated to understand the role of the different elastic properties of layers in the aortic dissection. The complex mechanical interaction between blood flow and wall dynamics in a three-dimensional arch model of an aorta was studied by means of computational coupled fluid-structure interaction analysis. The results show that stresses in the media layer are highest in three layers and that shear stress is concentrated in the media layer near to the adventitia layer. Hence, the difference in the elastic properties of the layers could be responsible for the pathological state in which a tear splits across the tunica media to near to the tunica adventitia and the dissection spreads along the laminar planes of the media layer where it is near the adventitia layer.
摘要
研究了主动脉壁应力对主动脉壁各层弹性的响应,以了解各层不同弹性特性在主动脉夹层中的作用。通过计算流体-结构耦合相互作用分析,研究了三维主动脉弓模型中血流与壁动力学之间复杂的力学相互作用。结果表明,中膜层的应力在三层中最高,且剪应力集中在靠近外膜层的中膜层。因此,各层弹性特性的差异可能是导致撕裂穿过中膜至接近外膜且夹层沿靠近外膜层的中膜层平面扩展的病理状态的原因。
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