Optimizing tendon repair and regeneration: how does the in vivo environment shape outcomes following rupture of a tendon such as the Achilles tendon?

Hart, David A.; Ahmed, Aisha S.; Chen, Junyu; Ackermann, Paul W.

doi:10.3389/fbioe.2024.1357871

Front. Bioeng. Biotechnol.

2024

DOI: 10.3389/fbioe.2024.1357871

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Optimizing tendon repair and regeneration: how does the in vivo environment shape outcomes following rupture of a tendon such as the Achilles tendon?

David A. Hart,

Aisha S. Ahmed,

Junyu Chen

et al.

Abstract: Risk for rupture of the Achilles tendon, and other tendons increases with age. Such injuries of tissues that function in high load environments generally are believed to heal with variable outcome. However, in many cases, the healing does not lead to a good outcome and the patient cannot return to the previous level of participation in active living activities, including sports. In the past few years, using proteomic approaches and other biological techniques, reports have appeared that identify biomarkers tha… Show more

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Cited by 2 publications

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Electrical Stimulation Therapy – Dedicated to the Perfect Plastic Repair

Deng,

Luo,

Chen

et al. 2024

Advanced Science

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Tissue repair and reconstruction are a clinical difficulty. Bioelectricity has been identified as a critical factor in supporting tissue and cell viability during the repair process, presenting substantial potential for clinical application. This review delves into various sources of electrical stimulation and identifies appropriate electrode materials for clinical use. It also highlights the biological mechanisms of electrical stimulation at both the subcellular and cellular levels, elucidating how these interactions facilitate the repair and regeneration processes across different organs. Moreover, specific electrode materials and stimulation sources are outlined, detailing their impact on cellular activity. The future development trends are projected from two perspectives: the optimization of equipment performance and the fulfillment of clinical demands, focusing on the feasibility, safety, and cost‐effectiveness of technologies.

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Electrical Stimulation Therapy – Dedicated to the Perfect Plastic Repair

Deng,

Luo,

Chen

et al. 2024

Advanced Science

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Panda Rope Bridge Technique promoted Achilles tendon regeneration in a novel rat tendon defect model

Shen,

Sun,

et al. 2024

Knee surg. sports traumatol. arthrosc.

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PurposeThis study aimed to determine whether the Achilles tendon tissue can undergo the pathological process of Achilles tendon regeneration after the Panda Rope Bridge Technique (PRBT).MethodsRats (n = 120) that operated with Achilles tendon rupture were divided into three treatment groups: Defect group (D group), PRBT group and Defect + Fix group (DF group). The D group represented natural healing with no treatment, the PRBT group represented healing receiving PRBT treatment and the DF group represented healing through conservative treatment by ankle fixation. The morphological, histological and biomechanical properties of the defective Achilles tendon were assessed at 7, 10, 12, 14, 28 and 56 days postoperatively.ResultsCompared to that observed in the other two groups, defected rat Achilles tendons that underwent PRBT recruited more cells earlier, eventually forming mature tendons, as revealed by histological analysis. PRBT also enabled defected tendons to regain stronger mechanical properties, thereby improving the prognosis. This improvement may be related to the earlier polarization of macrophages.ConclusionBy establishing and using a novel surgical model of Achilles tendon rupture in rats, most injured Achilles tendons can regenerate and regain normal histological properties, whereas tendons with other interventions formed fibrotic scar tissue. The strong regenerative capacity of tendon tissue enabled us to describe the pathological process of tendon regeneration after PRBT surgery in detail, which would aid in the treatment of tendon injuries. PRBT promotes Achilles tendon regeneration and has the potential to become a standard treatment.Level of EvidenceNot applicable.

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Optimizing tendon repair and regeneration: how does the in vivo environment shape outcomes following rupture of a tendon such as the Achilles tendon?

Cited by 2 publications

References 81 publications

Electrical Stimulation Therapy – Dedicated to the Perfect Plastic Repair

Electrical Stimulation Therapy – Dedicated to the Perfect Plastic Repair

Panda Rope Bridge Technique promoted Achilles tendon regeneration in a novel rat tendon defect model

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