Electrospun Heparin‐Loaded Core–Shell Nanofiber Sutures for Achilles Tendon Regeneration In Vivo

Achilles tendon reconstruction surgery is the primary clinical method for repairing acute Achilles tendon ruptures. However, the efficacy of the postoperative healing process and the recovery of physiological function are inadequate. This study examines the healing mechanism of ruptured rat Achilles tendons seamed with heparin‐loaded core–shell fiber sutures fabricated via near‐field electrospinning. High‐heparin‐concentration sutures (PPH3.0) perform better than the low‐heparin‐concentration sutures and commercial sutures (CSs). The PPH3.0 suture recruits fewer inflammatory cells and shows good histocompatibility in peritoneal implantation experiments. Staining of the Achilles tendon rupture repair zone demonstrates that a high heparin concentration in sutures reduces immune‐inflammatory responses. Immunohistochemical analysis reveals that the transforming growth factor‐β staining scores of the PPH3.0 sutures are not significantly different from those of the corresponding control group but are significantly different from those of the CSs and non‐heparin‐loaded‐suture groups. According to vascular endothelial growth factor (VEGF) analysis, the concentration of VEGF in the group treated with the PPH3.0 suture increases by 37.5% compared with that in its control group. No significant difference in tension strength is observed between the PPH3.0 group and healthy Achilles tendons. These findings illustrate that this novel method effectively treats Achilles tendon rupture and promotes healing and regeneration. This paper presents a novel treatment solution for acute Achilles tendon rupture. Heparin‐loaded core–shell nanofibers fabricated by near‐field electrospinning are twisted and braided into sutures to seam ruptured Achilles tendon of rat. High‐ heparin‐concentration sutures perform better than low‐heparin‐concentration sutures and commercial sutures.