Bian Weining, Bursac Nenad
Department of Biomedical Engineering, Duke University, Durham, NC 27708, USA.
Biomaterials. 2009 Mar;30(7):1401-12. doi: 10.1016/j.biomaterials.2008.11.015. Epub 2008 Dec 12.
The engineering of functional skeletal muscle tissue substitutes holds promise for the treatment of various muscular diseases and injuries. However, no tissue fabrication technology currently exists for the generation of a relatively large and thick bioartificial muscle made of densely packed, uniformly aligned, and differentiated myofibers. In this study, we describe a versatile cell/hydrogel micromolding approach where polydimethylsiloxane (PDMS) molds containing an array of elongated posts were used to fabricate relatively large neonatal rat skeletal muscle tissue networks with reproducible and controllable architecture. By combining cell-mediated fibrin gel compaction and precise microfabrication of mold dimensions including the length and height of the PDMS posts, we were able to simultaneously support high cell viability, guide cell alignment along the microfabricated tissue pores, and reproducibly control the overall tissue porosity, size, and thickness. The interconnected muscle bundles within the porous tissue networks were composed of densely packed, aligned, and highly differentiated myofibers. The formed myofibers expressed myogenin, developed abundant cross-striations, and generated spontaneous tissue contractions at the macroscopic spatial scale. The proliferation of non-muscle cells was significantly reduced compared to monolayer cultures. The more complex muscle tissue architectures were fabricated by controlling the spatial distribution and direction of the PDMS posts.
功能性骨骼肌组织替代物的工程化有望用于治疗各种肌肉疾病和损伤。然而,目前不存在用于生成由紧密排列、均匀排列且分化的肌纤维构成的相对大且厚的生物人工肌肉的组织制造技术。在本研究中,我们描述了一种通用的细胞/水凝胶微成型方法,其中含有一系列细长柱的聚二甲基硅氧烷(PDMS)模具被用于制造具有可重复和可控结构的相对大的新生大鼠骨骼肌组织网络。通过结合细胞介导的纤维蛋白凝胶压实和模具尺寸(包括PDMS柱的长度和高度)的精确微加工,我们能够同时支持高细胞活力,引导细胞沿着微加工的组织孔隙排列,并可重复地控制整体组织孔隙率、尺寸和厚度。多孔组织网络内相互连接的肌肉束由紧密排列、对齐且高度分化的肌纤维组成。形成的肌纤维表达肌细胞生成素,形成丰富的横纹,并在宏观空间尺度上产生自发的组织收缩。与单层培养相比,非肌肉细胞的增殖显著减少。通过控制PDMS柱的空间分布和方向制造出了更复杂的肌肉组织结构。