Bifurcations in valveless pumping techniques from a coupled fluid-structure-electrophysiology model in heart development

Q2 Agricultural and Biological Sciences
Nicholas A. Battista, L. Miller
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引用次数: 3

Abstract

We explore an embryonic heart model that couples electrophysiology and muscle-force generation to flow induced using a $2D$ fluid-structure interaction framework based on the immersed boundary method. The propagation of action potentials are coupled to muscular contraction and hence the overall pumping dynamics. In comparison to previous models, the electro-dynamical model does not use prescribed motion to initiate the pumping motion, but rather the pumping dynamics are fully coupled to an underlying electrophysiology model, governed by the FitzHugh-Nagumo equations. Perturbing the diffusion parameter in the FitzHugh-Nagumo model leads to a bifurcation in dynamics of action potential propagation. This bifurcation is able to capture a spectrum of different pumping regimes, with dynamic suction pumping and peristaltic-like pumping at the extremes. We find that more bulk flow is produced within the realm of peristaltic-like pumping.
心脏发育中流体-结构耦合电生理模型的无瓣泵送技术的分支
我们探索了一种胚胎心脏模型,该模型使用基于浸入边界法的$2D$流体-结构相互作用框架将电生理学和肌肉力量的产生与流动诱导相结合。动作电位的传播与肌肉收缩有关,因此与整体泵送动力学有关。与以前的模型相比,电动力学模型不使用规定的运动来启动泵送运动,而是泵送动力学完全耦合到由FitzHugh Nagumo方程控制的基础电生理模型。FitzHugh-Nagumo模型中扩散参数的扰动导致作用势传播动力学的分叉。这种分叉能够捕获一系列不同的泵送状态,在极端情况下具有动态抽吸泵送和蠕动式泵送。我们发现,在蠕动式泵送的范围内产生了更多的体积流量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Biomath
Biomath Agricultural and Biological Sciences-Agricultural and Biological Sciences (miscellaneous)
CiteScore
2.20
自引率
0.00%
发文量
6
审稿时长
20 weeks
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