Abstract
Achilles tendon injury has become a common sports injury clinically, and its treatment and rehabilitation are essential, while the regenerative capacity of the Achilles tendon in adult mammals is limited. Therefore, it is necessary to promote the repair and remodelling of the Achilles tendon through efficient interventions. Biodegradable polymer materials are one of the most popular in the treatment and repair of soft tissues, ligaments, muscles, and organs injured by organisms to enhance the function of their wounded sites. Thus, it plays a specific role in “compensation” and is widely used in clinical medicine and rehabilitation. This review summarized the progress of poly (ε-caprolactone), polylactic acid, poly (lactic-co-glycolic acid), poly (trimethylene carbonate) (PTMC), and polydioxanone (PDS) in repairing Achilles tendon injury, indicating that the biodegradable polymers have succeeded in improving and treating Achilles tendon injuries. However, some problems such as lack of good affinity with cells and uncontrollable degradation of the biodegradable polymers should be overcome in repairing Achilles tendon injury. Therefore, the development of modified biodegradable polymers to make them an ideal repair material that meets the requirements is vital in improving Achilles tendon injuries. With the continuous development and close cooperation of life sciences and material sciences, excellent materials for repairing Achilles tendon injuries will undoubtedly be produced. The treatment of Achilles tendon injuries will be more straightforward, which will be a boon for many athletes.
Highlights
The Achilles tendon is the largest and most powerful tendon in the human body, laying the foundation for our lower limb activities
The results showed that highly aligned PCL scaffolds tended to downregulate the expression of matrix metalloproteinases (MMPs) because of their high catabolic activity; Czarnecki et al (2012) investigated the feasibility of PCL-modified composite fibre-carbon scaffolds and analyzed their mechanical properties and ability to support the growth and proliferation of human dermal fibroblasts
The results showed that the migration and proliferation of rabbit dermal fibroblasts (RDFBs) on the arranged nanofiber scaffolds tended to stretch in a parallel direction along with the arrangement of nanofibers, which was conducive to promoting soft tissue healing around Achilles tendon defects and improving the effectiveness and reliability of the scaffolds in vitro
Summary
Biodegradable polymer materials are one of the most popular in the treatment and repair of soft tissues, ligaments, muscles, and organs injured by organisms to enhance the function of their wounded sites. It plays a specific role in “compensation” and is widely used in clinical medicine and rehabilitation. This review summarized the progress of poly (ε-caprolactone), polylactic acid, poly (lacticco-glycolic acid), poly (trimethylene carbonate) (PTMC), and polydioxanone (PDS) in repairing Achilles tendon injury, indicating that the biodegradable polymers have succeeded in improving and treating Achilles tendon injuries.
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