离体猪气管异向力学特性及数值模拟研究
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黑龙江省普通本科高等学校青年创新人才培养计划(UNPYSCT-2020194)


Study on Anisotropy Properties of in vitro Pig Trachea and Numerical Simulation
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    摘要:

    目的 研究猪气管和主支气管各向异性的力学性能,通过有限元数值模拟确定描述气管变形的本构模型。方法 将收集的猪气管沿轴向剖开并展成平面,以展开后的气管长度方向0°为起始角度,逆时针方向获得30°、60°、90°、120°、150°、180°共6个角度方向的标本。利用电子万能试验机分别对6个角度方向标本进行单轴拉伸试验,获得标本在不同角度方向的应力和应变。采用Mooney-Rivilin超弹性模型对实验数据进行非线性拟合,得到模型材料特性参数,建立气管和主支气管有限元模型,并进行拉伸数值模拟。结果 不同角度的气管标本拉伸呈现出不同的应力-应变;在气管中,30°、120°和150°方向样本的应力范围为1.0~1.5 MPa,60°和90°方向标本的应力范围为0.5~1.0 MPa,180°方向标本的应力范围为2.5~3.0 MPa;在主支气管中,30°、60°和150°方向标本的应力范围为0.8~1.0 MPa,90°和180°方向标本的应力范围为1.4~1.8 MPa,120°方向标本的应力范围为0.4~0.6 MPa,气管与主支气管有着明显的差异。经有限元模拟验证,Mooney-Rivilin本构模型适合于描述气管的小变形行为。结论 猪气管呈现较强的各向异性,Mooney-Rivilin模型可以表征气管小变形行为。研究结果为临床治疗中气管切除重建及支气管镜等手术器械介入治疗提供理论依据。

    Abstract:

    Objective To study mechanical properties of the anisotropy for pig trachea and main bronchi, and determine the constitutive model of trachea deformation by finite element numerical simulation. Methods The pig tracheas were collected and cut through in their axial directions and expanded into two-dimensional planes. Then, by setting the length direction of the trachea aortas as 0°, each planar trachea was anticlockwisely cut into 6 samples with orientation of 30°,60°,90°,120°,150° and 180°, respectively. Uniaxial tensile tests were applied on the specimen in 6 angular directions by using the electronic universal test machine, to obtain stress and strain of the specimen in different directions. Nonlinear fitting to the experimental data was performed by using the Mooney-Rivilin hyperelastic model, in order to obtain the material characteristic parameters. Finite element models of the trachea and the main bronchi were established, and tensile numerical simulation was carried out.Results Samples at different angles showed different stress-strain curves. In the trachea, the stresses of samples with angle of 30°, 120° and 150° were in the range of 1.0-1.5 MPa, the stresses of samples with angle of 60° and 90° were in the range of 0.5-1.0 MPa, and the stresses of samples with angle of 180° were in the range of 2.5-3.0 MPa. In the main bronchi, the stresses of samples with angle of 30°, 120° and 150° were in the range of 0.8-1.0 MPa, the stresses of samples with angle of 90° and 180° were in the range of 1.4-1.8 MPa, and the stresses of samples with angle of 120° were in the range of 0.4-0.6 MPa. There was an obvious difference between the trachea and the main bronchi. The finite element simulation verified that the Mooney-Rivilin constitutive model was suitable for describing small deformation behavior of the trachea. Conclusions The pig trachea exhibits strong anisotropy. Meanwhile, the Mooney-Rivilin model can characterize small tracheal deformations. The results provide theoretical references for tracheal resection and reconstruction in clinical treatment and intervention with surgical instruments such as bronchoscopy.

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魏雯,司利钢,王亚君,鲍玉冬,齐东博.离体猪气管异向力学特性及数值模拟研究[J].医用生物力学,2022,37(2):231-237

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  • 收稿日期:2021-04-09
  • 最后修改日期:2021-07-07
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  • 在线发布日期: 2022-04-27
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