3D Printing of a Biomimetic Myotendinous Junction Assisted by Artificial Intelligence†

IF 5.8 3区 医学 Q1 MATERIALS SCIENCE, BIOMATERIALS
Wisarut Kiratitanaporn, Jiaao Guan, Min Tang, Yi Xiang, Ting-yu Lu, Alis Balayan, Alison Lao, David B. Berry and Shaochen Chen
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Abstract

The myotendinous junction (MTJ) facilitates force transmission between muscle and tendon to produce joint movement. The complex microarchitecture and regional mechanical heterogeneity of the myotendinous junction pose major challenges in creating this interface in vitro. Engineering this junction in vitro is challenging due to substantial fabrication difficulties in creating scaffolds with intricate microarchitecture and stiffness heterogeneity to mimic the native muscle–tendon interface. To address the current challenges in creating the MTJ in vitro, digital light processing (DLP)-based 3D printing was used to fabricate poly(glycerol sebacate)acrylate (PGSA)-based muscle–tendon scaffolds with physiologically informed microstructure and mechanical properties. Local mechanical properties in various regions of the scaffold were tuned by adjusting the exposure time and light intensity used during the continuous DLP-based 3D printing process to match the mechanical properties present in distinct regions of native muscle–tendon tissue using printing parameters defined by an artificial intelligence-trained algorithm. To evaluate how the presence of zonal stiffness regions can affect the phenotype of a 3D-printed MTJ in vitro model, three 3D-printed PGSA-based scaffold conditions were investigated: (1) a scaffold with muscle-informed mechanical properties in its entirety without zonal stiffness regions, (2) a scaffold with one end possessing native muscle stiffness and the other end possessing native tendon stiffness, and (3) a scaffold with three distinct regions whose stiffness values correspond to those of muscle on one end of the scaffold, MTJ in the middle junction of the scaffold, and tendon on the other end of the scaffold. The scaffold containing regional mechanical heterogeneity most similar to the native MTJ (condition 3) was found to enhance the expression of MTJ-related markers compared to those without the presence of zonal stiffness regions. Overall, the DLP-based 3D printing platform and biomaterial system developed in this study could serve as a useful tool for mimicking the complexity of the native MTJ, which possesses inherent geometric and mechanical heterogeneity.

Abstract Image

在人工智能辅助下三维打印仿生肌腱连接体
肌腱连接处(MTJ)有助于肌肉和肌腱之间的力传递,从而产生关节运动。肌腱连接处复杂的微结构和区域机械异质性给体外创建这一界面带来了重大挑战。由于在制作具有复杂微结构和硬度异质性的支架以模拟原生肌肉-肌腱界面时存在巨大的制造困难,因此在体外制造这种交界处具有挑战性。为了解决目前在体外制造 MTJ 所面临的挑战,研究人员利用基于数字光处理(DLP)的三维打印技术制造了具有生理学微结构和机械性能的聚癸二酸甘油酯丙烯酸酯(PGSA)肌肉肌腱支架。在基于DLP的连续三维打印过程中,通过调整曝光时间和光照强度来调整支架各区域的局部机械特性,从而利用人工智能训练算法定义的打印参数来匹配原生肌腱组织不同区域的机械特性。为了评估分区刚度区域的存在如何影响体外 3D 打印 MTJ 模型的表型,研究了三种基于 PGSA 的 3D 打印支架条件:(1)支架整体具有肌肉力学特性,但不存在带状硬度区域;(2)支架一端具有原生肌肉硬度,另一端具有原生肌腱硬度;(3)支架具有三个不同的区域,其硬度值分别对应支架一端的肌肉、支架中间交界处的 MTJ 和支架另一端的肌腱。与不存在带状硬度区域的支架相比,含有与原生 MTJ 最为相似的区域机械异质性的支架(条件 3)可增强 MTJ 相关标记物的表达。总之,本研究中开发的基于 DLP 的三维打印平台和生物材料系统可作为一种有用的工具,用于模拟具有固有几何和机械异质性的原生 MTJ 的复杂性。
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来源期刊
Biomaterials Science
Biomaterials Science MATERIALS SCIENCE, BIOMATERIALS-
CiteScore
11.50
自引率
4.50%
发文量
556
期刊介绍: Biomaterials Science is an international high impact journal exploring the science of biomaterials and their translation towards clinical use. Its scope encompasses new concepts in biomaterials design, studies into the interaction of biomaterials with the body, and the use of materials to answer fundamental biological questions.
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