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A microfluidic shear device that accommodates parallel high and low stress zones within the same culturing chamber

机译:一种微流体剪切装置可在同一培养室内容纳平行的高应力区和低应力区

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摘要

Fluid shear stress (FSS) plays a critical role in regulating endothelium function and maintaining vascular homeostasis. Current microfluidic devices for studying FSS effects on cells either separate high shear stress zone and low shear stress zone into different culturing chambers, or arranging the zones serially along the flow direction, which complicates subsequent data interpretation. In this paper, we report a diamond shaped microfluidic shear device where the high shear stress zone and the low shear stress zone are arranged in parallel within one culturing chamber. Since the zones with different shear stress magnitudes are aligned normal to the flow direction, the cells in one stress group are not substantially affected by the flow-induced cytokine/chemokine releases by cells in the other group. Cell loading experiments using human umbilical vein endothelial cells show that the device is able to reveal stress magnitude-dependent and loading duration-dependent cell responses. The co-existence of shear stress zones with varied magnitudes within the same culturing chamber not only ensures that all the cells are subject to the identical culturing conditions, but also allows the resemblance of the differential shear stress pattern in natural arterial conditions. The device is expected to provide a new solution for studying the effects of heterogeneous hemodynamic patterns in the onset and progression of various vascular diseases.
机译:流体剪切应力(FSS)在调节内皮功能和维持血管稳态方面起着关键作用。当前用于研究FSS对细胞的影响的微流体装置将高剪切应力区和低剪切应力区分隔到不同的培养室中,或将这些区沿流动方向连续排列,这使后续的数据解释变得复杂。在本文中,我们报告了一种菱形微流体剪切装置,其中高剪切应力区和低剪切应力区在一个培养室内平行排列。由于具有不同剪应力大小的区域垂直于流动方向排列,因此一个应力组中的细胞基本上不受另一组细胞中流动诱导的细胞因子/趋化因子释放的影响。使用人脐静脉内皮细胞的细胞加载实验表明,该设备能够揭示应力幅度依赖性和加载持续时间依赖性的细胞反应。在同一培养室内同时存在大小不同的剪切应力区域,不仅可以确保所有细胞都经受相同的培养条件,而且还可以在自然动脉条件下模拟不同的剪切应力模式。该设备有望为研究异质血液动力学模式在各种血管疾病的发作和发展中的作用提供一种新的解决方案。

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