{"title":"振动粘附细胞培养物中细胞内变形动态的实时成像。","authors":"Toshihiko Shiraishi, Katsuya Sato","doi":"10.1002/bit.28793","DOIUrl":null,"url":null,"abstract":"<p>Mechanical vibration has been shown to regulate cell proliferation and differentiation in vitro and in vivo. However, the mechanism of its cellular mechanotransduction remains unclear. Although the measurement of intracellular deformation dynamics under mechanical vibration could reveal more detailed mechanisms, corroborating experimental evidence is lacking due to technical difficulties. In this study, we aimed to propose a real-time imaging method of intracellular structure deformation dynamics in vibrated adherent cell cultures and investigate whether organelles such as actin filaments connected to a nucleus and the nucleus itself show deformation under horizontal mechanical vibration. The proposed real-time imaging was achieved by conducting vibration isolation and making design improvements to the experimental setup; using a high-speed and high-sensitivity camera with a global shutter; and reducing image blur using a stroboscope technique. Using our system, we successfully produced the first experimental report on the existence of the deformation of organelles connected to a nucleus and the nucleus itself under horizontal mechanical vibration. Furthermore, the intracellular deformation difference between HeLa and MC3T3-E1 cells measured under horizontal mechanical vibration agrees with the prediction of their intracellular structure based on the mechanical vibration theory. 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引用次数: 0
摘要
研究表明,机械振动可在体外和体内调节细胞的增殖和分化。然而,其细胞机械传导机制仍不清楚。虽然测量机械振动下的细胞内形变动态可以揭示更详细的机制,但由于技术上的困难,目前还缺乏确凿的实验证据。在本研究中,我们旨在提出一种振动粘附细胞培养物中细胞内结构形变动态的实时成像方法,并研究与细胞核相连的肌动蛋白丝和细胞核本身等细胞器是否会在水平机械振动下发生形变。通过对实验装置进行振动隔离和设计改进,使用带有全局快门的高速高灵敏度相机,以及使用频闪镜技术减少图像模糊,实现了拟议的实时成像。利用我们的系统,我们成功地制作了第一份实验报告,说明在水平机械振动下,与细胞核相连的细胞器和细胞核本身存在变形。此外,在水平机械振动下测得的 HeLa 细胞和 MC3T3-E1 细胞的胞内形变差异与根据机械振动理论对其胞内结构的预测一致。这些结果为机械振动下的细胞机械传导机制提供了新的发现。
Real-time imaging of intracellular deformation dynamics in vibrated adherent cell cultures
Mechanical vibration has been shown to regulate cell proliferation and differentiation in vitro and in vivo. However, the mechanism of its cellular mechanotransduction remains unclear. Although the measurement of intracellular deformation dynamics under mechanical vibration could reveal more detailed mechanisms, corroborating experimental evidence is lacking due to technical difficulties. In this study, we aimed to propose a real-time imaging method of intracellular structure deformation dynamics in vibrated adherent cell cultures and investigate whether organelles such as actin filaments connected to a nucleus and the nucleus itself show deformation under horizontal mechanical vibration. The proposed real-time imaging was achieved by conducting vibration isolation and making design improvements to the experimental setup; using a high-speed and high-sensitivity camera with a global shutter; and reducing image blur using a stroboscope technique. Using our system, we successfully produced the first experimental report on the existence of the deformation of organelles connected to a nucleus and the nucleus itself under horizontal mechanical vibration. Furthermore, the intracellular deformation difference between HeLa and MC3T3-E1 cells measured under horizontal mechanical vibration agrees with the prediction of their intracellular structure based on the mechanical vibration theory. These results provide new findings about the cellular mechanotransduction mechanism under mechanical vibration.
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