He Shan, Pang Wei, Wu Xiaoyu, Yang Yang, Li Wenjun, Qi Hang, Yang Kai, Duan Xuexin, Wang Yanyan
State Key Laboratory of Precision Measuring Technology and Instruments, College of Precision Instruments and Optoelectronics Engineering, Tianjin University, Tianjin 300072, China.
ACS Nano. 2022 May 24;16(5):8427-8439. doi: 10.1021/acsnano.2c02980. Epub 2022 May 13.
Cell mechanical motion is a key physiological process that relies on the dynamics of actin filaments. Herein, a localized shear-force system based on gigahertz acoustic streaming (AS) is proposed, which can simultaneously realize intracellular delivery and cellular mechanical regulation. The results demonstrate that gold nanorods (AuNRs) can be delivered into the cytoplasm and even the nuclei of cancer and normal cells within a few minutes by AS stimulation. The delivery efficiency of AS stimulation is four times higher than that of endocytosis. Moreover, AS can effectively promote cytoskeleton assembly, regulate cell stiffness and change cell morphology. Since the inhibitory effect of AuNRs on cytoskeleton assembly, this AuNRs-AS system is able to inhibit or promote cell mechanical motion in a controlled manner by regulating the mechanical properties of cells. The bidirectional regulation of cell motion is further verified via scratch experiments, in which AuNRs-treated cells recover their motion ability through AS stimulation. In particular, the results of AuNRs-AS mechanical regulation on cell are related to the intrinsic properties of cell lines, revealing to more obvious effects on the cells with higher motor capacities. In summary, this acoustic technology has shown superiorities in controllable cell-motion manipulation, indicating its potential in building a multifunctional, integrated cytomechanics regulation platform.
细胞机械运动是一个依赖于肌动蛋白丝动力学的关键生理过程。在此,提出了一种基于千兆赫兹声流(AS)的局部剪切力系统,其能够同时实现细胞内递送和细胞机械调节。结果表明,通过AS刺激,金纳米棒(AuNRs)可在几分钟内递送至癌细胞和正常细胞的细胞质甚至细胞核中。AS刺激的递送效率比内吞作用高四倍。此外,AS能有效促进细胞骨架组装、调节细胞硬度并改变细胞形态。由于AuNRs对细胞骨架组装有抑制作用,该AuNRs-AS系统能够通过调节细胞的力学性质以可控方式抑制或促进细胞机械运动。通过划痕实验进一步验证了细胞运动的双向调节,其中经AuNRs处理的细胞通过AS刺激恢复其运动能力。特别地,AuNRs-AS对细胞的机械调节结果与细胞系的内在特性相关,显示出对具有较高运动能力的细胞有更明显的影响。总之,这种声学技术在可控的细胞运动操纵方面已显示出优势,表明其在构建多功能、集成的细胞力学调节平台方面具有潜力。
