Three-dimensional biofabrication of nanosecond laser micromachined nanofibre meshes for tissue engineered scaffolds.

Biomaterials Translational Pub Date : 2023-06-28 eCollection Date: 2023-01-01 DOI:10.12336/biomatertransl.2023.02.005
Ross H McWilliam, Wenlong Chang, Zhao Liu, Jiayuan Wang, Fengxuan Han, Richard A Black, Junxi Wu, Xichun Luo, Bin Li, Wenmiao Shu
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Abstract

There is a high demand for bespoke grafts to replace damaged or malformed bone and cartilage tissue. Three-dimensional (3D) printing offers a method of fabricating complex anatomical features of clinically relevant sizes. However, the construction of a scaffold to replicate the complex hierarchical structure of natural tissues remains challenging. This paper reports a novel biofabrication method that is capable of creating intricately designed structures of anatomically relevant dimensions. The beneficial properties of the electrospun fibre meshes can finally be realised in 3D rather than the current promising breakthroughs in two-dimensional (2D). The 3D model was created from commercially available computer-aided design software packages in order to slice the model down into many layers of slices, which were arrayed. These 2D slices with each layer of a defined pattern were laser cut, and then successfully assembled with varying thicknesses of 100 μm or 200 μm. It is demonstrated in this study that this new biofabrication technique can be used to reproduce very complex computer-aided design models into hierarchical constructs with micro and nano resolutions, where the clinically relevant sizes ranging from a simple cube of 20 mm dimension, to a more complex, 50 mm-tall human ears were created. In-vitro cell-contact studies were also carried out to investigate the biocompatibility of this hierarchal structure. The cell viability on a micromachined electrospun polylactic-co-glycolic acid fibre mesh slice, where a range of hole diameters from 200 μm to 500 μm were laser cut in an array where cell confluence values of at least 85% were found at three weeks. Cells were also seeded onto a simpler stacked construct, albeit made with micromachined poly fibre mesh, where cells can be found to migrate through the stack better with collagen as bioadhesives. This new method for biofabricating hierarchical constructs can be further developed for tissue repair applications such as maxillofacial bone injury or nose/ear cartilage replacement in the future.

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用于组织工程支架的纳秒激光微加工纳米纤维网的三维生物制造。
人们对定制移植物以替代受损或畸形骨和软骨组织的需求很大。三维(3D)打印提供了一种制造临床相关尺寸的复杂解剖特征的方法。然而,构建支架以复制天然组织的复杂分层结构仍具有挑战性。本文报告了一种新型生物制造方法,该方法能够制造出与解剖学相关尺寸的复杂设计结构。电纺纤维网的有益特性最终可以在三维环境中实现,而不是目前有望在二维环境中实现的突破。三维模型是利用市面上的计算机辅助设计软件包创建的,目的是将模型切成多层切片,并将这些切片排列起来。这些二维切片的每一层都有确定的图案,经激光切割后,以 100 μm 或 200 μm 的不同厚度成功地组装在一起。这项研究表明,这种新型生物制造技术可用于将非常复杂的计算机辅助设计模型复制成具有微米和纳米分辨率的分层结构,在临床上可制造出尺寸从 20 毫米的简单立方体到 50 毫米高的复杂人耳。为了研究这种分层结构的生物相容性,还进行了体外细胞接触研究。细胞在微机械电纺聚乳酸-共聚乙醇酸纤维网片上的存活率,在激光切割的孔径范围为 200 μm 至 500 μm 的阵列中,细胞在三周后的汇合值至少达到 85%。细胞还被播种到一个更简单的堆叠结构上,尽管该结构是用微机械加工的聚纤维网制成的,但在胶原蛋白作为生物粘合剂的作用下,细胞能更好地在堆叠结构中迁移。这种生物制造分层结构的新方法可进一步开发用于组织修复应用,如颌面骨损伤或鼻/耳软骨置换。
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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CiteScore
6.70
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发文量
9
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