Yamashita Tadahiro, Kollmannsberger Philip, Mawatari Kazuma, Kitamori Takehiko, Vogel Viola
Laboratory of Applied Mechanobiology, Department of Health Sciences and Technology, ETH Zurich, Vladimir-Prelog Weg 4, 8093 Zurich, Switzerland; Department of Bioengineering, School of Engineering, The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, 113-8656 Tokyo, Japan.
Laboratory of Applied Mechanobiology, Department of Health Sciences and Technology, ETH Zurich, Vladimir-Prelog Weg 4, 8093 Zurich, Switzerland.
Acta Biomater. 2016 Nov;45:85-97. doi: 10.1016/j.actbio.2016.08.044. Epub 2016 Aug 22.
Despite of the progress made to engineer structured microtissues such as BioMEMS and 3D bioprinting, little control exists how microtissues transform as they mature, as the misbalance between cell-generated forces and the strength of cell-cell and cell-substrate contacts can result in unintended tissue deformations and ruptures. To develop a quantitative perspective on how cellular contractility, scaffold curvature and cell-substrate adhesion control such rupture processes, human aortic smooth muscle cells were grown on glass substrates with submillimeter semichannels. We quantified cell sheet detachment from 3D confocal image stacks as a function of channel curvature and cell sheet tension by adding different amounts of Blebbistatin and TGF-β to inhibit or enhance cell contractility, respectively. We found that both higher curvature and higher contractility increased the detachment probability. Variations of the adhesive strength of the protein coating on the substrate revealed that the rupture plane was localized along the substrate-extracellular matrix interface for non-covalently adsorbed adhesion proteins, while the collagen-integrin interface ruptured when collagen I was covalently crosslinked to the substrate. Finally, a simple mechanical model is introduced that quantitatively explains how the tuning of substrate curvature, cell sheet contractility and adhesive strength can be used as tunable parameters as summarized in a first semi-quantitative phase diagram. These parameters can thus be exploited to either inhibit or purposefully induce a collective detachment of sheet-like microtissues for the use in tissue engineering and regenerative therapies.
Despite of the significant progress in 3D tissue fabrication technologies at the microscale, there is still no quantitative model that can predict if cells seeded on a 3D structure maintain the imposed geometry while they form a continuous microtissue. Especially, detachment or loss of shape control of growing tissue is a major concern when designing 3D-structured scaffolds. Utilizing semi-cylindrical channels and vascular smooth muscle cells, we characterized how geometrical and mechanical parameters such as curvature of the substrate, cellular contractility, or protein-substrate adhesion strength tune the catastrophic detachment of microtissue. Observed results were rationalized by a theoretical model. The phase diagram showing how unintended tissue detachment progresses would help in designing of mechanically-balanced 3D scaffolds in future tissue engineering applications.
尽管在设计诸如生物微机电系统(BioMEMS)和3D生物打印等结构化微组织方面取得了进展,但对于微组织在成熟过程中的转变却几乎没有控制手段,因为细胞产生的力与细胞间和细胞与基质接触的强度之间的失衡可能导致意外的组织变形和破裂。为了从定量角度研究细胞收缩性、支架曲率和细胞与基质的粘附如何控制此类破裂过程,将人主动脉平滑肌细胞接种在具有亚毫米级半通道的玻璃基板上。通过添加不同量的肌球蛋白抑制剂(Blebbistatin)和转化生长因子-β(TGF-β)分别抑制或增强细胞收缩性,我们从3D共聚焦图像堆栈中量化了细胞片层脱离情况,并将其作为通道曲率和细胞片层张力的函数。我们发现,更高的曲率和更高的收缩性都会增加脱离概率。对基板上蛋白质涂层粘附强度的变化研究表明,对于非共价吸附的粘附蛋白,破裂平面位于基板 - 细胞外基质界面,而当I型胶原蛋白与基板共价交联时,胶原蛋白 - 整合素界面会破裂。最后,引入了一个简单的力学模型,该模型定量解释了如何将基板曲率、细胞片层收缩性和粘附强度调谐作为可调参数,这在第一个半定量相图中进行了总结。因此,这些参数可用于抑制或有目的地诱导片状微组织的集体脱离,以用于组织工程和再生治疗。
尽管在微尺度3D组织制造技术方面取得了重大进展,但仍然没有定量模型能够预测接种在3D结构上的细胞在形成连续微组织时是否能保持所施加的几何形状。特别是,在设计3D结构支架时,生长组织的脱离或形状控制的丧失是一个主要问题。利用半圆柱形通道和血管平滑肌细胞,我们表征了诸如基板曲率、细胞收缩性或蛋白质 - 基板粘附强度等几何和力学参数如何调节微组织的灾难性脱离。通过理论模型对观察结果进行了合理化解释。展示意外组织脱离如何进展的相图将有助于未来组织工程应用中机械平衡的3D支架设计。
