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3D bioprinting of a biomimetic meniscal scaffold for application in tissue engineering

Jian Zhou, Zhuang Tian, Qinyu Tian, Peng Liqing, Kun Li, Xujiang Luo, Wang Diaodiao, Zhen Yang, Shuangpeng Jiang, Xiang Sui, Huang Jingxiang, Liu Shuyun, Hao Li-bo, Tang Peifu, Qi Yao, Guo Quanyi

2020Bioactive Materials107 citationsDOIOpen Access PDF

Abstract

Appropriate biomimetic scaffolds created via 3D bioprinting are promising methods for treating damaged menisci. However, given the unique anatomical structure and complex stress environment of the meniscus, many studies have adopted various techniques to take full advantage of different materials, such as the printing combined with infusion, or electrospining, to chase the biomimetic meniscus, which makes the process complicated to some extent. Some researchers have tried to tackle the challenges only by 3D biopringting, while its alternative materials and models have been constrained. In this study, based on a multilayer biomimetic strategy, we optimized the preparation of meniscus-derived bioink, gelatin methacrylate (GelMA)/meniscal extracellular matrix (MECM), to take printability and cytocompatibility into account together. Subsequently, a customized 3D bioprinting system featuring a dual nozzle + multitemperature printing was used to integrate the advantages of polycaprolactone (PCL) and meniscal fibrocartilage chondrocytes (MFCs)-laden GelMA/MECM bioink to complete the biomimetic meniscal scaffold, which had the best biomimetic features in terms of morphology and components. Furthermore, cell viability, mechanics, biodegradation and tissue formation in vivo were performed to ensure that the scaffold had sufficient feasibility and functionality, thereby providing a reliable basis for its application in tissue engineering.

Topics & Concepts

Scaffold3D bioprintingMeniscusMaterials scienceFibrocartilageTissue engineeringBiomedical engineeringExtracellular matrixGelatin3D printingNanotechnologyArticular cartilageChemistryComposite materialEngineeringOsteoarthritisAlternative medicineOpticsBiochemistryIncidence (geometry)MedicinePathologyPhysics3D Printing in Biomedical ResearchBone Tissue Engineering MaterialsAdditive Manufacturing and 3D Printing Technologies