Fabrication of a Magnetically Driven Cell-Stretching Device for Predefined Cell Alignment in Vitro

Pub Date : 2023-10-20 DOI:10.20965/jrm.2023.p1143
Tasuku Nakahara, Sora Ono, Kazuyuki Minami
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引用次数: 0

Abstract

Various devices have been developed that use stretching silicone sheets to evaluate cellular mechanotransduction. However, few studies have explored predefined cell alignments using mechanical stimuli for engineering applications, including cell sheets and drug screenings. Therefore, we proposed a magnetically driven cell-stretching device for predefined cell alignment in vitro , which consisted mainly of a circular silicone membrane with a neodymium magnet and standard cell culture dish. As the proposed device was incorporated into a cell culture dish, there may be a small risk of contamination in long-term incubation experiments. The device was fabricated by assembling a polydimethylsiloxane membrane and silicone ring. The fabricated device showed that the membrane strain increased with increasing voltage application to the electromagnet, and indicated that cell alignment occurs when strain exceeds 0.8%. Following cyclic stimulation of cells adhered to a membrane for 4 h in a CO 2 incubator with 1.05% strain at 0.1 Hz, cell alignment with the predefined direction increased by 20.4% compared to that before stimulation. The findings imply that the proposed device may be utilized for predefined cell alignment.
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磁性驱动细胞拉伸装置的制备及体外细胞定位
已经开发了各种设备,使用拉伸硅胶片来评估细胞机械转导。然而,很少有研究利用机械刺激探索用于工程应用的预定义细胞排列,包括细胞片和药物筛选。因此,我们提出了一种用于体外细胞预先定位的磁性细胞拉伸装置,该装置主要由带有钕磁铁的圆形硅胶膜和标准细胞培养皿组成。由于所提出的装置被纳入细胞培养皿中,因此在长期孵育实验中可能存在小的污染风险。该装置由聚二甲基硅氧烷膜和硅环组装而成。实验结果表明,薄膜应变随外加电压的增加而增加,当外加电压超过0.8%时,薄膜发生细胞排列。在0.1 Hz、1.05%浓度的co2培养箱中,将细胞粘附在膜上4小时,循环刺激后,细胞与预定方向的排列比刺激前增加了20.4%。研究结果表明,所提出的设备可用于预定义的细胞对齐。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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