A Vibrating-string Model for Closed-loop Wave Transmission and Reflection Between the Aorta and Periphery

Z. Hao
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Abstract

A tube-load model is used to reconstruct aortic pressure waveform from peripheral pressure waveform. Yet, the reconstructed aortic pressure waveform is greatly affected by load impedance used. In this work, a vibrating-string model for closed-loop wave transmission and reflection between the aorta and periphery is developed to examine the roles of all the parameters involved in aortic pressure waveform. The arterial pulsatile wave theory gives rise to the standard 1D wave equation for a vibrating string. A vibrating-string model based on radial displacement of the arterial wall is developed to relate aortic pressure waveform to peripheral pressure waveform, relate load impedance to input impedance, and derive theoretical expressions for associated clinical indices. The vibrating-string model is extended to incorporate blood velocity, and is further connected to the left ventricle (LV) to study the role of the LV in aortic pressure waveform. The difference between the vibrating-string model and the tube-load model is also examined. Load impedance is identified as an indispensable independent parameter for reconstruction of aortic pressure waveform with accuracy, and its physiologically realistic harmonic-dependence can only be obtained from the measured input impedance. The derived expressions for clinical indices interpret some clinical findings and underscore the role of harmonics in clinical indices. Some misconceptions in the tube-load model are revealed, including load impedance and characteristic impedance. This work clarifies the role of harmonics-dependence of load impedance and harmonics of aortic pressure waveform in determining clinical indices.
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主动脉与外周间闭环波传输与反射的振动弦模型
采用管载模型从外周压力波形重构主动脉压力波形。然而,重构的主动脉压波形受负载阻抗的影响较大。在这项工作中,建立了主动脉和周围之间闭环波传输和反射的振动弦模型,以检查主动脉压力波形中涉及的所有参数的作用。动脉脉动波理论给出了振动弦的标准一维波动方程。建立了基于动脉壁径向位移的振动弦模型,将主动脉压力波形与外周压力波形、负载阻抗与输入阻抗联系起来,推导出相关临床指标的理论表达式。将振动弦模型进行扩展,纳入血流速度,并进一步连接左心室(LV),研究左心室在主动脉压波形中的作用。分析了弦振模型与管柱载荷模型的差异。负载阻抗是准确重建主动脉压波形不可缺少的独立参数,其生理真实的谐波依赖性只能由测量的输入阻抗获得。推导出的临床指标表达式解释了一些临床发现,强调了谐波在临床指标中的作用。揭示了管负载模型中存在的一些误解,包括负载阻抗和特性阻抗。这项工作阐明了负载阻抗的谐波依赖性和主动脉压波形的谐波在确定临床指标中的作用。
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