Clinical Study on the Safety and Efficacy of Tendon Stem Progenitor Cells Therapy for Rotator Cuff Tears

Summary

Tendon injury is one of the most common sports injuries, including local tissue degeneration at the tendon insertion site following inflammation caused by long-term joint movement, friction, or strain, as well as acute traumatic tendon tears and defects of varying degrees due to sports. It is a recognized therapeutic challenge in orthopedics and sports medicine. With the increase in people's physical activities and changes in work styles, tendon injuries have become increasingly prevalent, with at least 30 million tendon injury cases annually. Meanwhile, tendon injuries pose a significant threat to the careers of many elite athletes. Currently, clinical treatments for tendon injuries mainly remain at the stages of physical therapy, surgical suture, and transplantation. Although these treatments have certain effects, their efficacy is limited-primarily because adult tendons lack complete regenerative capacity. As a result, the quality of repaired tendons is far inferior to that of normal tendons, making them prone to tendon adhesion, poor structural and mechanical properties, and frequent re-rupture. Even autologous tendon transplantation can only achieve approximately 40% of the mechanical properties of normal tendons, accompanied by excessive scar tissue formation. Current therapeutic and tissue engineering approaches can only partially improve tendon repair quality, failing to induce complete tendon repair and regeneration. Therefore, exploring new and efficient strategies for the treatment and regeneration of tendon injuries is of great significance.

In recent years, cell therapy has brought new opportunities for improving the repair quality of soft tissues such as tendons. Tendon-derived cells are isolated and extracted from tendons. These cells not only possess stem cell characteristics similar to bone marrow mesenchymal stem cells but also highly express tendon-specific genes and proteins. Therefore, this study intends to first culture and expand tendon stem/progenitor cells (TSPCs) to form therapeutic agents, then apply TSPC-enhanced therapy intraoperatively to patients with rotator cuff tendinopathy, and evaluate its clinical safety and efficacy.

Conditions

• Rotator Cuff Tendinopathy

Interventions

BIOLOGICAL

Stem cell therapy

For patients in the TSPCs group, after removing the arthroscopic fluid, the prepared TSPCs loaded on a scaffold were injected into the tendon - bone junction and over the repaired tendon using a spinal needle. Fibrin glue (Fibrin Sealant (Human), RAAS) served as the scaffold. The TSPCs suspension was first mixed with thrombin solution at a 3:1 ratio. Then, using the DUPLOJECT syringe support system (Fibrin Sealant (Human), RAAS), 2 ml of cell - thrombin suspension was combined with 2 ml of fibrinogen solution at a 1:1 ratio and applied to the repaired tendon surface. After extracting the arthroscopic fluid, this cell - thrombin - fibrinogen suspension was implanted under arthroscopic guidance. A probe was used to spread and adjust the fibrin glue to cover the repaired tendon - bone junction and tendon surface.

PROCEDURE

Conventional rotator cuff repair.

All procedures were performed under general anesthesia. Patients were in a beach-chair position. After glenohumeral inspection, subacromial decompression was conducted, and acromioplasty was performed. After subacromial decompression, the upper surface of the greater tuberosity was abraded to create a bleeding cancellous bone bed. The footprint of the greater tuberosity was debrided. Rotator cuff repair was performed using a double-row suture bridge technique. For medial-row repair, a hole was punched in the greater tuberosity, and a bioabsorbable suture anchor was inserted. After the medial row was completed, the suture limbs were used to create suture bridges over the tendon. The lateral fixation points were placed, and the suture anchor was used for lateral-row fixation.

Sponsors & Collaborators

• Second Affiliated Hospital, School of Medicine, Zhejiang University

  lead OTHER

Study Design

Allocation

RANDOMIZED

Purpose

TREATMENT

Masking

TRIPLE

Model

PARALLEL

Eligibility

Min Age

18 Years

Max Age

70 Years

Sex

ALL

Healthy Volunteers

No

Timeline & Regulatory

Start

2026-05-31

Primary Completion

2028-06-30

Completion

2029-01-31