ObjectiveTo investigate the mechanism of muscle-derived cells (MDCs) in repairing sciatic nerve defects in mice by observing the early growth of damaged peripheral nerves.MethodsThe hind limb skeletal muscles of mice carrying enhanced green fluorescent protein (EGFP) was collected to extract and culture EGFP-MDCs to P1 generation for later experiments. Five-mm-long nerve defects were created in the right sciatic nerves of C57BL/6 mice to establish a peripheral nerve defect model. The two stumps of sciatic nerve were bridged with 7-mm-long polyurethane (PUR) conduit. For the MDC group, EGFP-MDCs were injected into the PUR conduit. The PUR group without EGFP-MDCs was used as the negative control group. At 1 and 2 weeks after operation, the proximal and distal nerve stumps of the surgical side were collected to generally observe the early growth of nerve. Immunofluorescence staining of S100β, the marker of Schwann cells, was performed on longitudinal frozen sections of nerve tissues to calculate the maximum migration distance of Schwann cells, and observe the source of the Schwann cells expressing S100β. Immunofluorescence staining of phosphorylated erb-b2 receptor tyrosine kinase 2 (p-ErbB2) and phosphorylated focal adhesion kinase (p-FAK) in transverse frozen sections of nerve tissue was performed to calculate the positive rates of both proteins.ResultsThe general observation showed that the proximal and distal stumps of the surgical side in PUR group were not connected at 1 and 2 weeks after operation, while the bilateral nerve stumps in the MDC group were connected at 2 weeks after operation. Immunofluorescence staining showed that the Schwann cells expressing S100β in proximal and distal nerve stumps of PUR group and MDC group was not connected at 1 week after operation. At 2 weeks after operation, the Schwann cells expressing S100β in the two nerve stumps of the MDC group were connected, but not in the PUR group. At 2 weeks after operation, the sum of the maximum migration distance of Schwann cells in the regenerated nerve in both two groups was significantly increased when compared with that in each group at 1 week after operation, and that of MDC group was significantly higher than that in the PUR group at both 1 and 2 weeks after operation, the differences were all significant (P<0.05). At 1 week after operation, the positive rates of p-ErbB2 and p-FAK in the proximal nerve stump of MDC group were significantly higher than those in PUR group (P<0.05). There was no significant difference in the positive rate of p-ErbB2 of proximal stump between the two groups at 2 weeks after operation (t=0.327, P=0.747), while the positive rate of p-FAK of MDC group was significantly higher than that of PUR group (t=4.470, P=0.000). At 1 and 2 weeks after operation, the positive rates of p-ErbB2 and p-FAK in the distal stump of MDC group were significantly higher than those in PUR group (P<0.05). At 1 and 2 weeks after operation, part of Schwann cells expressing S100β, which were derived from EGFP-MDCs, could be observed in the regenerated nerves of MDC group.ConclusionMDCs can promote the phosphorylation of ErbB2 and FAK in the nerve stumps of mice, and promote the migration of Schwann cells. MDCs can be differentiated into cells expressing the Schwann cell marker S100β, or as other cellular components, to involve in the early repair of peripheral nerves.
ObjectiveTo explore the feasibility of using indocyanine green angiography in mapping the superficial temporal vessels and assisting design and harvesting of the superficial temporal artery based forehead flap. Methods A clinical data of 14 patients with facial soft tissue defects repaired with superficial temporal artery based forehead flaps between October 2015 and November 2022 was retrospectively analyzed. There were 9 males and 5 females with a median age of 9.5 years (range, 3-38 years). The forehead flaps were used to reconstruct facial soft tissue defects following excision of facial scar (8 cases) or congenital melanocyte nevus (6 cases). The size of defects ranged from 3 cm×2 cm to 24 cm×9 cm. Before operation, the indocyanine green angiography was used to map the superficial temporal artery and vein, and to analyze the relationship of the arteries and veins. The forehead flaps with unilateral superficial temporal fascia as the pedicle was transferred to repair the small facial defect in 2 cases. The facial pedicle contained the frontal branch of the superficial temporal artery and 2 cm of the superficial temporal fascia around the vessel, and the tiny accompanying vein of the frontal branch of the superficial temporal artery was used as the outflow of the flap. The forehead flaps with the skin pedicle including bilateral or unilateral superficial temporal fascia and the overlying skin was pre-expanded and transferred to repair the large facial defect in 12 cases. The skin pedicle contained the frontal branch of superficial temporal artery and one of main branches of superficial temporal vein. Among the 12 cases, the frontal branch of superficial temporal vein was used as the outflow in 4 cases, and the parietal branch was used as the outflow in 8 cases. The size of the flaps ranged from 3 cm×2 cm to 30 cm×13 cm. The skin pedicles were divided at 3 weeks after the flap transfer. ResultsIndocyanine green angiography could clearly showed the course and branching of the superficial temporal artery and vein. Individual differences existed in the location where the frontal branch of the superficial temporal artery entered the forehead. The superficial temporal vein had great variability and did not follow the artery. One patient had expander-related complication, which resulted in 3-cm flap necrosis. The necrotic tissue was debrided and repaired with skin grafting. The other flaps totally survived and the incisions healed by first intention. All patients were followed up 2-24 months, with a median of 11.5 months. The color, texture, and thickness of the flaps matched well with those of recipient sites. Hypertrophic scar was not observed in recipient or donor site. All patients were satisfied with the reconstructive outcomes. ConclusionIndocyanine green angiography can clearly visualize the course and the branches of the superficial temporal arteries and veins, which can help surgeons understand the position, distribution, and concomitant relationship of the superficial temporal vessels, and make a rational surgical plan of the forehead flap.
Objective To review the research progress of the principle and clinical application of keloid core excision technique. Methods The literature on keloid core excision technique at home and abroad in recent years was extensively reviewed, and the principle, development history, indications, advantages and disadvantages of this technique were summarized, and the existing controversies were analyzed. Results Keloid core excision is a technique to remove the inner fibrous core from the keloid and cover the defect with the keloidal flap. It reduces the wound tension, yields good aesthetic results in the treatment of ear keloids, and reduces the recurrence rate of keloids combining with adjuvant therapies. Conclusion The keloid core excision technique has specific advantages, yet its overall efficacy remains controversial. Further studies are imperative to explore the mechanisms regarding keloid recurrence and the vascular supply principles of the keloidal flap. It is also necessary to define appropriate surgical indications and safety protocols of this technique.