Lagrangian properties of the blood flow through human and murine aortic arches: towards improved customised therapies and diagnostic techniques

Simone Ghiglia, Marco Mazzuoli, Joel Guerrero
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Abstract

The mass transport properties of the blood flow in the aortic arch are investigated by means of direct numerical simulations. The aortic arches in human and murine cases are assumed to be similar (with similarity factor equal to 20) and characterised by constant diameter, while the axis lays on a plane. The simulations were carried out using OpenFOAM (v.10). The flow regime appears remarkably different in the two cases because flow separation and vortical structures appear during the systolic phases in the human case, which are absent at the mouse scale. Consequently, peaks of the wall-shear-stress occur at different phases and, in the murine case, are characterised by a magnitude nearly 4 times larger than in the human case. The trajectories of fluid particles are computed in order to evaluate the dispersion efficiency exploited by biomedical applications (e.g. drug delivery or solid micro carriers). Despite the different flow regimes, in both system particles uniformly released at the inlet preserve a homogeneous distribution as they flow in the aortic arch. In particular, during the early decelerating phases of systole, the fluid trajectories are found frequently to approach the zones of the wall where the shear-stress is large.
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人体和小鼠主动脉弓血流的拉格朗日特性:改进定制疗法和诊断技术
通过直接数值模拟研究了主动脉弓中血流的质量传输特性。假设人和小鼠的主动脉弓相似(相似系数等于 20),直径恒定,轴线位于一个平面上。模拟使用 OpenFOAM (v.10) 进行。两种情况下的流动机制明显不同,因为在人体情况下,收缩阶段会出现流动分离和涡流结构,而在小鼠情况下则没有。因此,壁面剪切应力的峰值出现在不同的阶段,在小鼠的情况下,峰值几乎是人类情况下的 4 倍。计算流体颗粒的轨迹是为了评估生物医学应用(如药物输送或固体微载体)的分散效率。尽管流态不同,但在这两个系统中,在入口处均匀释放的粒子在主动脉弓中流动时保持了均匀分布。特别是在收缩早期减速阶段,流体轨迹经常接近剪应力较大的壁区。
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