分岔微血管网络中的气泡倒伏:微流控模型

A. Calderón, Y. Heo, D. Huh, F. Nobuyuki, S. Takayama, J. Fowlkes, J. Bull
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引用次数: 0

摘要

在小微动脉分叉的微流控模型中研究了心血管气泡的倒伏。这些实验解决了气泡在分岔中倒伏机制的动力学问题。这项工作的动机是一种新的气体栓塞治疗技术,用于肿瘤梗死治疗癌症的潜在治疗。实验模型微动脉分叉由透明弹性体(聚二甲基硅氧烷)构建。单个气泡悬浮在分叉母管中的水中,并通过对大气压力开放的定高程储层施加指定的驱动压力。研究了驱动压力和气泡大小对气泡倒伏的影响。结果表明,在分岔中产生气泡的压力小于产生气泡的压力。也可以用气泡遮挡整个分岔和多个分岔装置。在倒伏到移位压力的范围内,我们观察到气泡分裂的不稳定性。根据结果,我们估计栓塞治疗产生的气泡可以停留在直径为21微米或更小的血管中。这些发现可能有助于制定气体栓塞治疗中的微泡输送策略
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Bubble lodging in bifurcating microvessel networks: a microfluidic model
Lodging of cardiovascular gas bubbles is investigated in a microfluidic model of small arteriole bifurcations. These experiments address the dynamics of the lodging mechanism of gas bubbles in bifurcations. This work is motivated by a novel gas embolotherapy technique for the potential treatment of cancer by tumor infarction. The experimental model arteriole bifurcations were constructed from a transparent elastomer (polydimethylsiloxane). A single air bubble was suspended in water within the parent tube of the bifurcation and a specified driving pressure was imposed via constant elevation reservoirs that were open to atmospheric pressure. The driving pressure and bubble size were varied, and their effects on the bubble lodging were assessed. The results show that the pressure to lodge a bubble in a bifurcation is less than to dislodge it. It was also possible to occlude an entire bifurcation and multiple bifurcation devices with bubbles. Splitting ratios were assessed in the range of lodging to dislodging pressure where we observed an instability in bubble splitting. From the results we estimate that gas bubbles from embolotherapy can lodge in vessels 21 mum or smaller in diameter. These findings may be useful in developing strategies for microbubble delivery in gas embolotherapy
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