水阻力不对称分布中苍蝇翅脉的位置效应

Symmetry Pub Date : 2024-09-15 DOI:10.3390/sym16091212
Kazuki Sugiyama, Yoshihiro Kubota, Osamu Mochizuki
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引用次数: 0

摘要

昆虫翅脉网络有助于血液运输,但对其结构的血液动力学影响尚不清楚。果蝇的后交叉静脉(PCV)破坏了网络拓扑结构的对称性,并减少了血液运输过程中的总压力损失;然而,其不同位置对不同物种的影响尚未得到研究。本研究调查了这种静脉不同连接位置对血液动力学的影响。通过将静脉网络类比为液压回路,利用普瓦休伊定律和基尔霍夫定律得出了静脉内的流速和压力损失。结果表明,在靠近机翼底部的两个 PCV 连接处,总压力损失都有所下降。在模仿网络拓扑结构的理想化电路中,应用与机翼边缘一样的单侧高液压阻力,显示出与实际网络中相同的压力损失响应,但不是在对称的阻力分布范围内。因此,在非对称阻力分布范围内,最靠近基部的 PCV 可使压力损失最小化,这表明某些物种在进化过程中适应了在靠近基部的位置使用这种静脉来减少压力损失。我们的发现突显了苍蝇翅膀形态的可能优化,以同时保持液体运输网络和飞行装置的功能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Positional Effects of a Fly’s Wing Vein in the Asymmetric Distribution of Hydraulic Resistances
Insect wing vein networks facilitate blood transport with unknown haemodynamic effects on their structures. Fruit flies have the posterior cross vein (PCV) that disrupts the symmetry of the network topology and reduces the total pressure loss during blood transport; however, the impact of its various positions among species has not been examined. This study investigated the haemodynamic effects of this vein with various connecting positions. By analogising venous networks to hydraulic circuits, the flow rates and pressure losses within the veins were derived using Poiseuille’s and Kirchhoff’s laws. The results showed that the total pressure loss decreased for both PCV connections near the wing’s base. In an idealised circuit imitating the network topology, applied high hydraulic resistances as one-sided as those along the edge of the wing, the same pressure loss response as that in the actual network was demonstrated, but not within a symmetric resistance distribution. Therefore, the most proximal PCV minimises the pressure loss within the asymmetric resistance distribution, indicating an evolutionary adaptation to reducing the pressure loss in certain species with this vein near the base. Our findings highlight the possible optimisation of the flies’ wing morphology to maintain the functions of the liquid transport networks and flight devices simultaneously.
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