Skeletal muscle tissue engineering using functional magnetite nanoparticles

A. Ito, Hirokazu Akiyama, Yasunori Yamamoto, Y. Kawabe, M. Kamihira
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Abstract

Skeletal muscular tissues were constructed using magnetic force-based tissue engineering (Mag-TE) techniques. Mouse myoblast C2C12 cells labeled with magnetite cationic liposomes (MCLs) were seeded into a well of 24-well ultra-low cell attachment culture plates. When a magnet was positioned underneath the well, cells accumulated evenly onto the culture surface and formed a multilayered cell sheet. Furthermore, because an angiogenic potential of transplants is considered to be important for the long-term maintenance of cell survival and tissue functions, a vascular endothelial growth factor (VEGF) gene-modified C2C12 (C2C12/VEGF) cell sheets were also fabricated by the Mag-TE technique. The secretion level of C2C12/VEGF sheets was 3.0 ng/day, indicating that VEGF gene-expressing cell sheets were successfully fabricated. Since the shape of artificial tissue constructs can be controlled by magnetic force, a cellular string-like assembly was formed by placing a linear-shaped magnetic field concentrator with a magnet. These cellular sheets and strings shrank and did not maintain their shapes for an additional in vitro culture period during myogenic differentiation. On the other hand, when a silicone plug was positioned at the center of well during the fabrication of cell sheets, the cell sheets shrank and formed a ring-like assembly around the plug. After 6-d cultivation of cell rings in differentiation medium, the C2C12 cells differentiated to form multinucleated myotubes. Thus, these procedures can provide a novel strategy for skeletal muscular tissue engineering.
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利用功能性磁铁矿纳米颗粒进行骨骼肌组织工程
采用磁力组织工程技术构建骨骼肌组织。用磁性阳离子脂质体(mcl)标记的小鼠成肌细胞C2C12细胞接种于24孔超低细胞附着培养板中。当磁铁放置在孔下时,细胞均匀地聚集在培养表面并形成多层细胞片。此外,由于移植的血管生成潜力被认为对细胞存活和组织功能的长期维持很重要,因此我们还利用mage -te技术制备了血管内皮生长因子(VEGF)基因修饰的C2C12 (C2C12/VEGF)细胞片。C2C12/VEGF片的分泌量为3.0 ng/d,表明VEGF基因表达细胞片制备成功。由于人工组织结构的形状可以由磁力控制,因此通过将线形磁场集中器与磁铁放置在一起形成细胞弦状组装体。在肌源性分化过程中,这些细胞片和细胞串收缩,并不能在体外培养期间保持其形状。另一方面,在制造电池片的过程中,当硅塞被放置在井的中心位置时,电池片会收缩,并在塞周围形成环状组合。细胞环在分化培养基中培养6 d后,C2C12细胞分化形成多核肌管。因此,这些方法可以为骨骼肌组织工程提供一种新的策略。
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