The formation of a stably perfused microvasculature continues to be a major challenge in tissue engineering. Previous work has suggested the importance of a sufficiently large transmural pressure in maintaining vascular stability and perfusion. Here we show that a system of empty channels that provides a drainage function analogous to that of lymphatic microvasculature in vivo can stabilize vascular adhesion and maintain perfusion rate in dense, hydraulically resistive fibrin scaffolds in vitro. In the absence of drainage, endothelial delamination increased as scaffold density increased from 6 to 30 mg/mL and scaffold hydraulic conductivity decreased by a factor of 20. Single drainage channels exerted only localized vascular stabilization, the extent of which depended on the distance between vessel and drainage as well as scaffold density. Computational modeling of these experiments yielded an estimate of 0.40-1.36 cm H2O for the minimum transmural pressure required for vascular stability. We further designed and constructed fibrin patches (0.8 × 0.9 cm(2)) that were perfused by a parallel array of vessels and drained by an orthogonal array of drainage channels; only with the drainage did the vessels display long-term stability and perfusion. This work underscores the importance of drainage in vascularization, especially when a dense, hydraulically resistive scaffold is used.
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机译:稳定灌注的微脉管系统的形成仍然是组织工程中的主要挑战。先前的工作表明足够大的透壁压力对维持血管稳定性和灌注的重要性。在这里,我们显示了一个空通道系统,该系统提供的排水功能类似于体内的淋巴微血管系统,可以稳定血管黏附并在体外的致密,抗水力性纤维蛋白支架中维持灌注速率。在没有引流的情况下,随着支架密度从6增加到30 mg / mL,而支架的水力传导率下降了20倍,内皮层的剥离增加。单个引流通道仅发挥局部血管稳定作用,其程度取决于血管之间的距离排水和脚手架密度。这些实验的计算模型得出血管稳定性所需的最小透壁压力估计为0.40-1.36 cm H2O。我们进一步设计和构建了纤维蛋白斑块(0.8×0.9 cm(2)),这些斑块通过平行的血管阵列进行灌注,并通过正交的排水通道进行排水。只有通过引流,血管才显示出长期的稳定性和灌注。这项工作强调了血管形成中引流的重要性,尤其是在使用致密的液压阻力支架时。
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