Caleb C. Berggren, David Jiang, Y. F. Jack Wang, Jake A. Bergquist, Lindsay C. Rupp, Zexin Liu, Rob S. MacLeod, Akil Narayan, Lucas H. Timmins
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In an idealized coronary\nartery geometry, a forward FE model for each parameter ensemble was created to\npredict tissue stresses under physiologic loading. An emulator was constructed\nwithin the UncertainSCI software using polynomial chaos techniques, and\nstatistics and sensitivities were directly computed. Results demonstrated that\nmaterial parameter uncertainty propagates to variability in predicted stresses\nacross the vessel wall, with the largest dispersions in stress within the\nadventitial layer. Variability in stress was most sensitive to uncertainties in\nthe anisotropic component of the strain energy function. Unary and binary\ninteractions within the adventitial layer were the main contributors to stress\nvariance, and the leading factor in stress variability was uncertainty in the\nstress-like material parameter summarizing contribution of the embedded fibers\nto the overall artery stiffness. 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引用次数: 0
摘要
临床采用患者特异性建模策略的核心是证明模拟结果是可靠和安全的。仿真框架必须对模型输入的不确定性具有稳健性,并且结果应具有可信度。在这项研究中,我们采用了不确定性量化-有限元(FE)耦合框架来了解血管材料属性的不确定性对预测应力变化的影响。根据人体冠状动脉组织特定层力学行为测试得出的材料参数拟合了单变量概率分布。假定参数在概率上是独立的,因此可以进行有效的参数集合采样。在理想化的冠状动脉几何形状中,为每个参数集合创建了一个前向 FE 模型,以预测生理负荷下的组织应力。利用多项式混沌技术在 UncertainSCI 软件中构建了一个仿真器,并直接计算了统计量和灵敏度。结果表明,材料参数的不确定性会导致整个血管壁预测应力的变化,其中ventitial层的应力分散最大。应力的变化对应变能函数各向异性分量的不确定性最为敏感。内膜层内的一元和二元相互作用是造成应力变异的主要因素,而应力变异的主要因素是应力样材料参数的不确定性,该参数概括了内嵌纤维对整个动脉刚度的贡献。患者特异性冠状动脉模型的结果证实了上述许多发现。总之,这凸显了材料特性变化对预测动脉应力的影响,并为探索和描述计算生物力学中的不确定性提供了一条途径。
Influence of Material Parameter Variability on the Predicted Coronary Artery Biomechanical Environment via Uncertainty Quantification
Central to the clinical adoption of patient-specific modeling strategies is
demonstrating that simulation results are reliable and safe. Simulation
frameworks must be robust to uncertainty in model input(s), and levels of
confidence should accompany results. In this study we applied a coupled
uncertainty quantification-finite element (FE) framework to understand the
impact of uncertainty in vascular material properties on variability in
predicted stresses. Univariate probability distributions were fit to material
parameters derived from layer-specific mechanical behavior testing of human
coronary tissue. Parameters were assumed to be probabilistically independent,
allowing for efficient parameter ensemble sampling. In an idealized coronary
artery geometry, a forward FE model for each parameter ensemble was created to
predict tissue stresses under physiologic loading. An emulator was constructed
within the UncertainSCI software using polynomial chaos techniques, and
statistics and sensitivities were directly computed. Results demonstrated that
material parameter uncertainty propagates to variability in predicted stresses
across the vessel wall, with the largest dispersions in stress within the
adventitial layer. Variability in stress was most sensitive to uncertainties in
the anisotropic component of the strain energy function. Unary and binary
interactions within the adventitial layer were the main contributors to stress
variance, and the leading factor in stress variability was uncertainty in the
stress-like material parameter summarizing contribution of the embedded fibers
to the overall artery stiffness. Results from a patient-specific coronary model
confirmed many of these findings. Collectively, this highlights the impact of
material property variation on predicted artery stresses and presents a
pipeline to explore and characterize uncertainty in computational biomechanics.