Department of Biomedical Engineering, University of Michigan, Ann Arbor, MI, USA.
Department of Biomechanics, University of Nebraska at Omaha, Omaha, NE, USA.
Acta Biomater. 2023 Oct 15;170:68-85. doi: 10.1016/j.actbio.2023.09.007. Epub 2023 Sep 10.
High failure rates present challenges for surgical and interventional therapies for peripheral artery disease of the femoropopliteal artery (FPA). The FPA's demanding biomechanical environment necessitates complex interactions with repair devices and materials. While a comprehensive understanding of the FPA's mechanical characteristics could improve medical treatments, the viscoelastic properties of these muscular arteries remain poorly understood, and the constitutive model describing their time-dependent behavior is absent. We introduce a new viscoelastic constitutive model for the human FPA grounded in its microstructural composition. The model is capable of detailing the contributions of each intramural component to the overall viscoelastic response. Our model was developed utilizing fractional viscoelasticity and tested using biaxial experimental data with hysteresis and relaxation collected from 10 healthy human subjects aged 57 to 65 and further optimized for high throughput and automation. The model accurately described the experimental data, capturing significant nonlinearity and hysteresis that were particularly pronounced circumferentially, and tracked the contribution of passive smooth muscle cells to viscoelasticity that was twice that of the collagen fibers. The high-throughput parameter estimation procedure we developed included a specialized objective function and modifications to enhance convergence for the common exponential-type fiber laws, facilitating computational implementation. Our new model delineates the time-dependent behavior of human FPAs, which will improve the fidelity of computational simulations investigating device-artery interactions and contribute to their greater physical accuracy. Moreover, it serves as a useful tool to investigate the contribution of arterial constituents to overall tissue viscoelasticity, thereby expanding our knowledge of arterial mechanophysiology. STATEMENT OF SIGNIFICANCE: The demanding biomechanical environment of the femoropopliteal artery (FPA) necessitates complex interactions with repair devices and materials, but the viscoelastic properties of these muscular arteries remain poorly understood with the constitutive model describing their time-dependent behavior being absent. We hereby introduce the first viscoelastic constitutive model for the human FPA grounded in its microstructures. This model was tested using biaxial mechanical data collected from 10 healthy human subjects between the ages of 57 to 65. It can detail the contributions of each intramural component to the overall viscoelastic response, showing that the contribution of passive smooth muscle cells to viscoelasticity is twice that of collagen fibers. The usefulness of this model as tool to better understand arterial mechanophysiology was demonstrated.
股腘动脉(FPA)外周动脉疾病的外科和介入治疗面临着高失败率的挑战。FPA 苛刻的生物力学环境需要与修复装置和材料进行复杂的相互作用。虽然全面了解 FPA 的机械特性可以改进医疗治疗方法,但这些肌肉动脉的粘弹性特性仍未被充分理解,并且缺乏描述其时变行为的本构模型。我们引入了一种新的基于 FPA 微观结构组成的人 FPA 粘弹性本构模型。该模型能够详细描述每个壁内成分对整体粘弹性响应的贡献。我们的模型是利用分数粘弹性开发的,并使用从 57 岁到 65 岁的 10 位健康人体收集的带有滞后和松弛的双轴实验数据进行了测试,并进一步针对高通量和自动化进行了优化。该模型准确地描述了实验数据,捕捉到了显著的非线性和滞后性,尤其是在圆周方向上,并且跟踪了被动平滑肌细胞对粘弹性的贡献,是胶原纤维的两倍。我们开发的高通量参数估计过程包括一个特殊的目标函数和修改,以增强常见指数型纤维律的收敛性,从而促进计算实现。我们的新模型描绘了人 FPA 的时变行为,这将提高研究装置-动脉相互作用的计算模拟的保真度,并有助于提高其物理准确性。此外,它还可以作为研究动脉成分对整体组织粘弹性贡献的有用工具,从而扩展我们对动脉机械生理学的知识。
股腘动脉(FPA)苛刻的生物力学环境需要与修复装置和材料进行复杂的相互作用,但这些肌肉动脉的粘弹性特性仍未被充分理解,并且缺乏描述其时变行为的本构模型。我们在此引入第一个基于其微观结构的人 FPA 粘弹性本构模型。该模型使用从 57 岁到 65 岁的 10 位健康人体收集的双轴力学数据进行了测试。它可以详细描述每个壁内成分对整体粘弹性响应的贡献,表明被动平滑肌细胞对粘弹性的贡献是胶原纤维的两倍。该模型作为更好地了解动脉机械生理学的工具的有用性得到了证明。
