Siegfried Weller Institute for Trauma Research, BG Trauma Clinic Tübingen, University of Tübingen, Tübingen, Germany.
Department of Biomedical Engineering, University of Michigan, Ann Arbor, MI, United States.
J Tissue Eng Regen Med. 2017 Dec;11(12):3508-3522. doi: 10.1002/term.2263. Epub 2017 Mar 29.
Controlling mesenchymal stromal cell (MSC) shape is a novel method for investigating and directing MSC behaviour in vitro. it was hypothesized that specifigc MSC shapes can be generated by using stiffness-defined biomaterial surfaces and by applying cyclic tensile forces. Biomaterials used were thin and thick silicone sheets, fibronectin coating, and compacted collagen type I sheets. The MSC morphology was quantified by shape descriptors describing dimensions and membrane protrusions. Nanoscale stiffness was measured by atomic force microscopy and the expression of smooth muscle cell (SMC) marker genes (ACTA2, TAGLN, CNN1) by quantitative reverse-transcription polymerase chain reaction. Cyclic stretch was applied with 2.5% or 5% amplitudes. Attachment to biomaterials with a higher stiffness yielded more elongated MSCs with fewer membrane protrusions compared with biomaterials with a lower stiffness. For cyclic stretch, compacted collagen sheets were selected, which were associated with the most elongated MSC shape across all investigated biomaterials. As expected, cyclic stretch elongated MSCs during stretch. One hour after cessation of stretch, however, MSC shape was rounder again, suggesting loss of stretch-induced shape. Different shape descriptor values obtained by different stretch regimes correlated significantly with the expression levels of SMC marker genes. Values of approximately 0.4 for roundness and 3.4 for aspect ratio were critical for the highest expression levels of ACTA2 and CNN1. Thus, specific shape descriptor values, which can be generated using biomaterial-associated stiffness and tensile forces, can serve as a template for the induction of specific gene expression levels in MSC. Copyright © 2017 John Wiley & Sons, Ltd.
控制间充质基质细胞(MSC)的形状是一种研究和指导 MSC 体外行为的新方法。假设通过使用具有特定刚度的生物材料表面和施加循环拉伸力,可以产生特定的 MSC 形状。使用的生物材料是薄而厚的硅树脂片、纤连蛋白涂层和压缩的 I 型胶原片。通过描述尺寸和膜突起的形状描述符来定量 MSC 形态。通过原子力显微镜测量纳米级刚度,并通过定量逆转录聚合酶链反应测量平滑肌细胞(SMC)标记基因(ACTA2、TAGLN、CNN1)的表达。施加 2.5%或 5%的振幅进行循环拉伸。与具有较低刚度的生物材料相比,与具有较高刚度的生物材料附着会产生具有较少膜突起的更细长的 MSC。对于循环拉伸,选择了压缩的胶原片,与所有研究的生物材料相比,压缩的胶原片与最细长的 MSC 形状相关。正如预期的那样,循环拉伸在拉伸过程中拉长了 MSC。然而,拉伸停止后 1 小时,MSC 形状又变圆了,表明拉伸诱导的形状丢失。通过不同的拉伸模式获得的不同形状描述符值与 SMC 标记基因的表达水平显著相关。接近 0.4 的圆度和 3.4 的纵横比值对于 ACTA2 和 CNN1 的最高表达水平是关键的。因此,使用与生物材料相关的刚度和拉伸力可以产生特定的形状描述符值,可以作为诱导 MSC 中特定基因表达水平的模板。版权所有 © 2017 约翰威立父子公司
