Development, Characterization and Cell Cultural Response of 3D Biocompatible Micro-Patterned Poly-ε- Caprolactone Scaffolds Designed and Fabricated Integrating Lithography and Micromolding Fabrication Techniques.

T. Limongi, E. Miele, V. Shalabaeva, R. Rocca, Rossana Schipani, N. Malara, F. Angelis, A. Giugni, E. Fabrizio
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引用次数: 5

Abstract

Scaffold design and fabrication are very important subjects for biomaterial, tissue engineering and regenerative medicine research playing a unique role in tissue regeneration and repair. Among synthetic biomaterials Poly-e- Caprolactone (PCL) is very attractive bioresorbable polyester due to its high permeability, biodegradability and capacity to be blended with other biopolymers. Thanks to its ability to naturally degrade in tissues, PCL has a great potential as a new material for implantable biomedical micro devices. This work focuses on the establishment of a micro fabrication process, by integrating lithography and micromolding fabrication techniques, for the realization of 3D microstructure PCL devices. Scaffold surface exhibits a combination in the patterned length scale; cylindrical pillars of 10 μm height and 10 μm diameter are arranged in a hexagonal lattice with periodicity of 30 μm and their sidewalls are nano-sculptured, with a regular pattern of grooves leading to a spatial modulation in the z direction. In order to demonstrate that these biocompatible pillared PCL substrates are suitable for a proper cell growth, NIH/3T3 mouse embryonic fibroblasts were seeded on them and cells key adhesion parameters were evaluated. Scanning Electron Microscopy and immunofluorescence analysis were carried out to check cell survival, proliferation and adhesion; cells growing on the PCL substrates appeared healthy and formed a well-developed network in close contact with the micro and nano features of the pillared surface. Those 3D scaffolds could be a promising solution for a wide range of applications within tissue engineering and regenerative medicine applications.
集成光刻和微成型技术设计和制造的三维生物相容性微图案聚ε-己内酯支架的开发、表征和细胞培养反应。
支架的设计与制造是生物材料、组织工程和再生医学研究的重要课题,在组织再生和修复中发挥着独特的作用。聚己内酯(PCL)具有高渗透性、可生物降解性和与其他生物聚合物共混的能力,是一种非常有吸引力的生物可吸收聚酯材料。由于其在组织中自然降解的能力,PCL作为植入式生物医学微设备的新材料具有很大的潜力。本工作的重点是建立一种微制造工艺,通过集成光刻和微成型制造技术,实现三维微结构的PCL器件。支架表面在图案长度尺度上呈现组合;高10 μm、直径10 μm的圆柱柱呈周期性30 μm的六角形晶格排列,其侧壁进行纳米雕刻,具有规则的凹槽图案,导致z方向的空间调制。为了证明这些生物相容性柱状PCL基质适合细胞生长,我们将NIH/3T3小鼠胚胎成纤维细胞接种在其上,并对细胞的关键粘附参数进行了评估。扫描电镜和免疫荧光检测细胞存活、增殖和粘附情况;在PCL基质上生长的细胞表现健康,并与柱状表面的微纳特征密切接触,形成了发育良好的网络。这些3D支架在组织工程和再生医学的广泛应用中是一个很有前途的解决方案。
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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