A Novel Bi-Directional and Bi-Temporal Delivery System for Enhancing Intrasynovial Tendon Repair.

Materials and interfaces Pub Date : 2024-01-01 Epub Date: 2024-10-18 DOI:10.53941/mi.2024.100001

Yidan Chen, Seth Kinoshita, Emily Yan, Min Hao, Hua Shen, Richard Gelberman, Stavros Thomopoulos, Younan Xia

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Abstract

Flexor tendon injuries are common and often require surgical repair and prolonged rehabilitation. Successful clinical outcomes depend on the concurrent suppression of adhesions (caused by inflammation) at the tendon surface and promotion of matrix synthesis inside the tendon. Herein, we report a bi-directional and bi-temporal drug delivery system designed to target both the initial inflammatory phase and the subsequent proliferative and remodeling phases of healing to improve outcomes after flexor tendon repair. The system features a multi-layered design with anti-adhesion and pro-matrix factors encapsulated in separate layers of hyaluronate films crosslinked to different degrees to control their direction and rate of release. After validating drug delivery under controlled release, cell culture experiments involving tendon fibroblasts and a Transwell system are conducted to demonstrate the system's efficacy in modulating local cellular responses. The promising results from this study lay the groundwork for moving this system toward in vivo testing and clinical translation.

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一种新型的双向双颞输送系统用于增强滑膜内肌腱修复。

屈肌腱损伤是常见的，通常需要手术修复和长期康复。成功的临床结果取决于同时抑制肌腱表面粘连（由炎症引起）和促进肌腱内基质合成。在此，我们报告了一种双向双颞叶药物输送系统，旨在针对初始炎症阶段和随后的增殖和重塑愈合阶段，以改善屈肌腱修复后的预后。该系统采用多层设计，将抗粘附因子和促基质因子封装在不同程度交联的透明质酸膜中，以控制其方向和释放速度。在控释下验证药物传递后，进行了肌腱成纤维细胞和Transwell系统的细胞培养实验，以证明该系统在调节局部细胞反应方面的功效。这项有希望的研究结果为将该系统推向体内测试和临床转化奠定了基础。

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Materials and interfaces

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