Hierarchy Reproduction: Multiphasic Strategies for Tendon/Ligament-Bone Junction Repair.

IF 9.6 Q1 ENGINEERING, BIOMEDICAL Biomaterials research Pub Date : 2025-01-22 eCollection Date: 2025-01-01 DOI:10.34133/bmr.0132

Kaiting Chen, Zezheng Liu, Xinying Zhou, Wanyu Zheng, He Cao, Zijian Yang, Zhengao Wang, Chengyun Ning, Qingchu Li, Huiyu Zhao

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Abstract

Tendon/ligament-bone junctions (T/LBJs) are susceptible to damage during exercise, resulting in anterior cruciate ligament rupture or rotator cuff tear; however, their intricate hierarchical structure hinders self-regeneration. Multiphasic strategies have been explored to fuel heterogeneous tissue regeneration and integration. This review summarizes current multiphasic approaches for rejuvenating functional gradients in T/LBJ healing. Synthetic, natural, and organism-derived materials are available for in vivo validation. Both discrete and gradient layouts serve as sources of inspiration for organizing specific cues, based on the theories of biomaterial topology, biochemistry, mechanobiology, and in situ delivery therapy, which form interconnected network within the design. Novel engineering can be constructed by electrospinning, 3-dimensional printing, bioprinting, textiling, and other techniques. Despite these efforts being limited at present stage, multiphasic scaffolds show great potential for precise reproduction of native T/LBJs and offer promising solutions for clinical dilemmas.

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分层再生：肌腱/韧带-骨连接处修复的多相策略。

在运动过程中，肌腱/韧带-骨连接处（T/LBJs）容易受到损伤，导致前交叉韧带断裂或肩袖撕裂；然而，它们复杂的等级结构阻碍了自我再生。已经探索了多相策略来促进异质组织再生和整合。本文综述了目前在T/LBJ愈合中恢复功能梯度的多相方法。合成、天然和生物衍生材料可用于体内验证。基于生物材料拓扑、生物化学、机械生物学和原位传递疗法的理论，离散和梯度布局都是组织特定线索的灵感来源，在设计中形成相互连接的网络。新的工程可以通过静电纺丝、三维打印、生物打印、纺织和其他技术来构建。尽管目前这些努力还很有限，但多相支架在精确复制天然T/LBJs方面显示出巨大的潜力，为临床难题提供了有希望的解决方案。

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Biomaterials research

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