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一种新型的圆柱双轴计算机控制生物反应器和用于血管组织工程的生物力学测试装置。

A novel cylindrical biaxial computer-controlled bioreactor and biomechanical testing device for vascular tissue engineering.

机构信息

The George W. Woodruff School of Mechanical Engineering, Georgia Institute of Technology, Atlanta, Georgia 30332-0405, USA.

出版信息

Tissue Eng Part A. 2009 Nov;15(11):3331-40. doi: 10.1089/ten.tea.2008.0369.

DOI:10.1089/ten.tea.2008.0369
PMID:19385725
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2792052/
Abstract

It is becoming evident that tissue-engineered constructs adapt to altered mechanical loading, and that specific combinations of multidirectional loads appear to have a synergistic effect on the remodeling. However, most studies of mechanical stimulation of engineered vascular tissue engineering employ only uniaxial stimulation. Here we present a novel computer-controlled bioreactor and biomechanical testing device designed to precisely and simultaneously control mean and cyclic values of transmural pressure (at rates up to 1 Hz and ranges of 40 mmHg), luminal flow rate, and axial length (or load) applied to gel-derived, scaffold-derived, and self-assembly-derived tissue-engineered blood vessels during culture, while monitoring vessel geometry with a resolution of 6.6 mum. Intermittent monitoring of the extracellular matrix and cells is accomplished on live tissues using multi-photon confocal microscopy under unloaded and loaded conditions at multiple time-points in culture (on the same vessel) to quantify changes in cell and extracellular matrix content and organization. This same device is capable of performing intermittent cylindrical biaxial biomechanical testing at multiple time-points in culture (on the same vessel) to quantify changes in the mechanical behavior during culture. Here we demonstrate the capabilities of this new device on self-assembly-derived and collagen-gel-derived tissue-engineered blood vessels.

摘要

很明显,组织工程构建物会适应改变的机械负荷,并且特定的多向负荷组合似乎对重塑具有协同作用。然而,大多数工程血管组织工程的机械刺激研究仅采用单轴刺激。在这里,我们提出了一种新颖的计算机控制的生物反应器和生物力学测试设备,旨在精确和同时控制跨壁压(高达 1 Hz 的速率和 40 mmHg 的范围)、管腔流速和轴向长度(或负载)的平均值和循环值,施加于凝胶衍生、支架衍生和自组装衍生的组织工程血管在培养过程中,同时使用分辨率为 6.6 µm 的方法监测血管几何形状。使用多光子共聚焦显微镜在未加载和加载条件下,在培养过程中的多个时间点(同一血管上)对活组织进行细胞外基质和细胞的间歇监测,以定量细胞和细胞外基质含量和组织的变化。同一设备能够在培养过程中的多个时间点(同一血管上)进行间歇圆柱双向生物力学测试,以定量培养过程中机械性能的变化。在这里,我们展示了这种新设备在自组装衍生和胶原凝胶衍生的组织工程血管上的功能。

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