ObjectiveTo review the nomenclature, functional unit construction, technical essentials, and prevention and treatment of complications of functional perforator flaps, so as to provide references for the structural and functional reconstruction of composite tissue defects. MethodsBy retrieving and analyzing domestic and foreign literatures on anatomical research, technical innovation and clinical application of functional design and application of perforator flaps, combined with the clinical practice of our team, the methods for harvesting and integrating functional units of perforator flaps were summarized. ResultsFunctional perforator flap refers to a perforator flap that, on the basis of perforator blood supply, carries one or more tissue functional units (such as muscles, nerves, lymphatic vessels, lymph nodes, bones, mucous membranes, joints or articular cartilages, etc.) with sufficient blood supply located in the supra-fascia and/or sub-fascia, and is used to reconstruct one or more functions of the recipient site. The design and transfer of functional perforator flaps should not only meet the needs of precise coverage of the wound, but also reconstruct the functions of the recipient site such as muscle contraction, flap sensation, lymphatic drainage, blood flow bridging, bone growth, glandular secretion or joint movement, while avoiding iatrogenic dysfunction in the donor site. ConclusionFunctional perforator flaps have broken through the limitation of “wound coverage” and realized the integrated reconstruction of “structure-function-aesthetics”.
Objective To explore the causes of vascular crisis after thumb and other finger reconstruction by toe-to-hand transfer and effective treatment methods so as to improve the survival rate of transplanted tissues. Methods Between February 2012 and October 2015, 59 cases of thumb and other finger defects were repaired with different hallux nail flaps with the same vascular pedicle flap to reconstruct thumb and other fingers and repair skin defect. The donor site was repaired by a perforator flap. A total of 197 free tissues were involved. There were 46 males and 13 females with the average age of 30.6 years (range, 18-42 years). Vascular crisis occurred in 21 free tissues (10.7%) of 17 patients, including 9 arterial crisis (4.6%) of 8 cases, and 12 venous crisis (6.1%) of 10 cases. Conservative treatment was performed first; in 8 free tissues of 7 cases after failure of conservative treatment, anastomotic thrombosis was found in 5 free tissues of 4 cases, twisted vascular pedicle in 1 free tissue of 1 case, surrounding hematoma in 1 free tissue of 1 case, and anastomotic thrombosis associated with hematoma in 1 free tissue of 1 case, which underwent clearing hematoma, resecting embolization, regulating vascular tension, re-anastomosis or vascular transplantation. Results In 8 cases of arterial crisis, 5 free tissues of 5 cases survived after conservative treatment; partial necrosis occurred in 1 free tissue (1 case) of 4 free tissues (3 cases) undergoing surgical exploration. In 10 cases of venous crisis, 1 free tissue necrosis and 1 free tissue partial necrosis occurred in 8 free tissues (6 cases) undergoing conservative treatment; partial necrosis occurred in 1 free tissue of 4 free tissues (4 cases) undergoing surgical exploration. Free flap and skin graft were performed on 2 free tissues of 4 cases having flap necrosis respectively. Conclusion Vascular crisis is complex and harmful to survival of transplanted tissue in reconstruction of the thumb and other fingers. Immediate intervention is helpful to obtain a higher survival rate.
Objective To explore the application value of infrared thermography in the design and harvesting of ultrathin anterolateral thigh perforator flaps. Methods Between June 2024 and December 2024, 9 cases of ultrathin anterolateral thigh perforator flaps were designed and harvested with the assistance of infrared thermography. There were 7 males and 2 females, aged 21-61 years (mean, 39.8 years). The body mass index ranged from 19.49 to 26.45 kg/m² (mean, 23.85 kg/m²). Causes of injury included 5 cases of traffic accident injuries and 4 cases of machine crush injuries. There were 3 cases of leg wounds, 2 cases of foot wounds, and 4 cases of hand wounds. After debridement, the size of wound ranged from 7 cm×4 cm to 13 cm×11 cm. The time from admission to flap repair surgery was 5-12 days (mean, 7 days). Preoperatively, perforator localization was performed using a traditional Doppler flow detector and infrared thermography, respectively. The results were compared with the actual intraoperative locations; a discrepancy ≤10 mm was considered as consistent localization (positive), and the positive predictive value was calculated. All 9 cases were repaired with ultrathin anterolateral thigh perforator flaps designed and harvested based on thermographic images. The size of flap ranged from 8 cm×5 cm to 14 cm×8 cm, with a thickness of 3-6 mm (mean, 5.2 mm). One donor site was repaired with a full-thickness skin graft, and the others were sutured directly. Postoperatively, anti-inflammatory, anticoagulant, and anti-vascular spasm treatments were administered, and follow-up was conducted. ResultsThe Doppler flow detector identified 22 perforating vessels within the set range, among which 16 were confirmed as superficial fascia layer perforators intraoperatively, with a positive predictive value of 72.7%. The infrared thermograph detected 23 superficial fascia layer perforating vessels, and 21 were verified intraoperatively, with a positive predictive value of 91.3%. There was no significant difference between the two methods [OR (95%CI)=3.93 (0.70, 22.15), P=0.100]. The perforator localization time of the infrared thermograph was (5.1±1.3) minutes, which was significantly shorter than that of the Doppler flow detector [(10.1±2.6) minutes], with a significant difference [MD (95%CI)=–5.00 (–7.08, –2.91), P<0.001]. Postoperatively, 1 case of distal flap necrosis healed after dressing changes; all other flaps survived successfully. The skin grafts at donor site survived, and all incisions healed by first intention. All patients were followed up 3-6 months (mean, 4.7 months). No pain or other discomfort occurred at the donor or recipient sites. All patients with foot wounds could walk with shoes, and no secondary flap revision was required. Flaps in 3 hand wound cases, 2 foot wound cases, and 3 leg wound cases recovered light touch and pressure sensation, but not pain or temperature sensation; the remaining 2 cases had no sensory recovery. ConclusionPreoperative localization using infrared thermography for repairing ultrathin anterolateral thigh perforator flaps can help evaluate the blood supply status of perforators, reduce complications, and improve surgical safety and flap survival rate.
Objective To review the clinical applications of perforator flaps in restoring human body functions. Methods An extensive literature review was conducted on both domestic and international publications to summarize the clinical use of perforator flaps for functional restoration. Results Perforator flaps are among the most commonly used flaps in reconstructive surgery. Beyond providing soft tissue repair, they are increasingly employed to reconstruct diverse bodily functions, leading us to propose the concept of the “functional perforator flap”. Although various forms of functional perforator flaps are currently utilized, reports are predominantly scattered case studies, lacking systematic organization. Commonly used functional perforator flaps can be categorized into five types: chimeric perforator flaps, perforator flaps for nerve function restoration, perforator flaps for lymphatic drainage enhancement, flow-through perforator flaps, and perforator flaps for restoring bone and joint motion. These novel flaps significantly broaden the application scope of perforator flaps, elevating the goal of reconstruction from mere wound repair to achieving repair concurrent with functional reconstruction. ConclusionThe application of various functional perforator flap designs significantly improves wound reconstruction outcomes and represents an effective approach for managing complex defects. Future developments will undoubtedly see more forms of functional perforator flaps reported to meet increasingly sophisticated reconstructive demands.