外周循环对全身搏动的自动调节反应的模拟研究。

Federico Aletti, Ettore Lanzarone, Maria Laura Costantino, Giuseppe Baselli
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引用次数: 7

摘要

背景:本模拟研究通过动脉树的集总模型和微循环的非线性模型,包括局部控制的血流和组织-毛细血管流体交换,研究了由于分布的外周血管活动而引起的总外周阻力(TPR)的潜在调节。结果:进行循环数值模拟,计算不同血流脉动度条件下的TPR,提取心血管系统的压力-流量特征。模拟结果表明,在没有搏动性的情况下,大动脉的TPR增加,而随着谐波含量的增加,TPR降低。这是一种典型的非线性效应,由于外周微血管床的主动、非线性自调节的贡献,这也产生了动脉血压和心输出量之间的非线性关系。结论:这项模拟研究虽然关注的是由脉搏性引起的TPR调节的简单效应,但表明在研究包括动脉树和外周血管床在内的全球心血管系统的综合行为时,非线性自调节机制不可忽视。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Simulation study of autoregulation responses of peripheral circulation to systemic pulsatility.

Simulation study of autoregulation responses of peripheral circulation to systemic pulsatility.

Simulation study of autoregulation responses of peripheral circulation to systemic pulsatility.

Simulation study of autoregulation responses of peripheral circulation to systemic pulsatility.

Background: This simulation study investigated potential modulations of total peripheral resistance (TPR), due to distributed peripheral vascular activity, by means of a lumped model of the arterial tree and a non linear model of microcirculation, inclusive of local controls of blood flow and tissue-capillary fluid exchange.

Results: Numerical simulations of circulation were carried out to compute TPR under different conditions of blood flow pulsatility, and to extract the pressure-flow characteristics of the cardiovascular system. Simulations showed that TPR seen by the large arteries was increased in absence of pulsatility, while it decreased with an augmented harmonic content. This is a typically non linear effect due to the contribution of active, non linear autoregulation of the peripheral microvascular beds, which also generated a nonlinear relationship between arterial blood pressure and cardiac output.

Conclusion: This simulation study, though focused on a simple effect attaining TPR modulation due to pulsatility, suggests that non-linear autoregulation mechanisms cannot be overlooked while studying the integrated behavior of the global cardiovascular system, including the arterial tree and the peripheral vascular bed.

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