Objective To explore the feasibility and effectiveness of perforator propeller flap sequential transfer technique in repair of soft tissue defect of distal lower extremity. Methods Between July 2015 and July 2021, 10 patients with soft tissue defect of distal lower extremity were treated with perforator propeller flap sequential transfer technique. There were 8 males and 2 females, with a median age of 47 years (range, 6-71 years). The etiologies included malignant tumor in 5 cases, trauma in 3 cases, postburn scar contracture in 1 case, and diabetic foot ulcer in 1 case. The defects were located at the pretibial area in 1 case, the distal lower extremity and Achilles tendon in 3 cases, the dorsum of foot and lateral malleolar area in 4 cases, the heel in 1 case, and the plantar foot in 1 case. The size of the defect ranged from 5 cm×3 cm to 8 cm×8 cm. Peroneal artery perforator propellor flaps (the 1st flap) in size of 14 cm×4 cm to 29 cm×8 cm were used to repair the defects of distal lower extremity. The donor site defects were repaired with the other perforator propeller flaps (the 2nd flap) in size of 7 cm×3 cm to 19 cm×7 cm. The donor site of the 2nd flap was directly closed. ResultsAll the operations were successfully completed and all of the 2nd flaps were elevated within 1 hour. Eight the 1st flaps survived completely; 2 had venous congestion. Among the 2 patients with venous congestion, 1 had necrosis of the distal end of the flap, and the secondary wound was repaired by skin grafting; 1 recovered spontaneously after 7 days. The 2nd flaps totally survived. No complication such as hematoma or infection occurred. Primary closure was achieved in all the recipient and donor sites. All patients were followed up 2-39 months, with a median of 15.5 months. The color, texture, and thickness of the flaps matched well with those of recipient sites. The normal contour of the leg was preserved. During follow-up, no recurrence of malignance or ulcer was observed. The scar contracture was completely released. All patients were satisfied with the reconstructive outcomes. Conclusion The application of the perforator propeller flap sequential transfer technique can improve the repair ability of the lower extremity perforator propeller flap while ensuring the first-stage closure of the donor site, thereby improving the effectiveness.
ObjectiveTo explore the feasibility and technical essentials of soft tissue defect reconstruction of the lower extremity using the distally based anteromedial thigh flap (dAMT) pedicled with perforating vessels from rectus femoris branch. MethodsBetween July 2008 and December 2015, 6 patients underwent defect reconstruction of the lower extremity using the dAMT flap pedicled with perforating vessels from rectus femoris branch. There were 4 males and 2 females with an average age of 34 years (range, 4-55 years). The etiologies included liposarcoma in 1 case, malignant fibrous histocytoma in 1 case, post-burn scar contracture around the ankle in 1 case, and post-burn scar contracture around the knee in 3 cases. The disease duration ranged from 3 to 28 months (mean, 13 months). After resection of lesion tissues, the defect size ranged from 13 cm×7 cm to 24 cm×12 cm. The flap size ranged from 15 cm×8 cm to 24 cm×12 cm. The length of the pedicle ranged from 10 to 25 cm (mean, 19.8 cm). The distance from the flap pivot point to the superolateral border of the patella ranged from 8 to 13 cm (mean, 11.3 cm). The donor sites were directly sutured. ResultsAll flaps survived postoperatively without any complications. All wounds at the donor and the recipient sites healed primarily. The patients were followed up from 5 to 36 months (mean, 17.8 months). The color, texture, and thickness of the flaps were similar to those of the surrounding skin. No tumor recurrence was observed. The range of motion of flexion and extension of the joint were greatly improved in the patients with scar contracture. ConclusionIf the rectus femoris branch gives off cutaneous branch to the anteromedial thigh region and arises from the descending branch of the lateral circumflex femoral artery, a dAMT flap could be raised to reconstruct soft tissue defects of the lower extremity.
Objective To explore the feasibility and technical points of soft tissue defect reconstruction of the lower extremity using the distally based anterolateral thigh (dALT) flap based on perforating vessels from the lateral circumflex femoral artery (LCFA) oblique branch. Methods Between July 2010 and July 2016, 7 patients underwent defect reconstruction of the lower extremities using the dALT flap based on perforating vessels from the LCFA oblique branch. There were 4 males and 3 females with an average age of 26.7 years (range, 3-58 years). The etiologies included angiofibrolipoma in 1 case, malignant fibrous sarcoma in 1 case, soft tissue sarcoma in 1 case, and post-burn scar contracture in 4 cases. The disease duration was 13 years, 1 year, and 8 months in 3 patients with tumors respectively, and was from 6 months to 35 years in 4 patients with post-burn scar contracture. After resection of lesion tissues, the defect size ranged from 8 cm×6 cm to 24 cm×8 cm. The flap size ranged from 9 cm×7 cm to 24 cm×8 cm. The length of the pedicle ranged from 12 to 22 cm (mean, 16.6 cm). The distance from the flap pivot point to the superolateral border of the patella ranged from 9.5 to 14.0 cm (mean, 11.8 cm). The donor sites were directly closed in 6 cases and covered with the split-thickness skin graft in 1 case. Results All flaps survived after surgery without any major complications. All wounds at the donor and the recipient sites healed primarily. The patients were followed up from 5 to 54 months (mean, 30.7 months). The color, texture, and thickness of the flaps were similar to those of the surrounding skin. No tumor recurrence was observed. The range of motion of flexion and extension of the knee joint were greatly improved in the patients with post-burn scar contracture. Conclusion For patients who have the oblique branch from the LCFA descending branch which sends out perforating vessels to the skin of the anterolateral thigh region, a dALT flap could be used to reconstruct soft tissue defects of the lower extremities.
Objective To explore the feasibility and effectiveness of sideburn reconstruction using the expanded island scalp flap based on the parietal branch of the superficial temporal vessel. Methods Between February 2012 and April 2015, 7 patients underwent sideburn reconstruction. There were 3 males and 4 females with an average age of 15 years (range, 4-44 years). The etiologies included burn injury in 3 cases, trauma in 1 case, radiation therapy in 1 case, and congenital melanocytic nevus in 2 cases. The size of the sideburn defects ranged from 5.0 cm×3.5 cm to 16.0 cm×10.0 cm. At the first-stage, according to the sideburn defect, a tissue expander of the appropriate size was inserted beneath the superficial temporal fascia which containing the parietal branch of the superficial temporal vessel. Postoperatively, regular saline injection was commenced. After 3-6 months of the first-stage surgery, the expander was adequately inflated. While the second-stage surgery was performed, the lesion was excised and the tissue expander removed. The expanded island scalp flap based on the parietal branch of the superficial temporal vessel was harvested and advanced towards the defect of the sideburn according to the contralateral normal one, and the size of flap ranged from 8 cm×3 cm to 17 cm×11 cm. The donor site was closed primarily. Results All flaps survived and the wound and donor sites were healed primarily without any complication. All patients were followed up 1-36 months (mean, 9.8 months). The profile, hair density, and hair direction of the new sideburn were similar to the contralateral sideburn. In 1 patient, the reconstructed sideburn was a little larger than the contralateral normal one. After laser hair removal, the patient was satisfied with the appearance. Conclusion The expanded island scalp flap based on the parietal branch of the superficial temporal vessel provides an effective option for the sideburn reconstruction, which presents with the similar appearance to the contralateral one.
ObjectiveTo explore the feasibility of using indocyanine green (ICG) angiography to detect brachial artery perforators, and the clinical application of brachial artery perforator propeller (BAPP) flaps to repair soft tissue defects of the trunk and upper limbs.MethodsBetween August 2016 and February 2019, ICG angiography was used to detect the perforating vessels of the brachial artery muscle septum, and the BAPP flaps were cut out with the detected perforating vessels as the pedicle to repair 19 cases of trunk and upper limb soft tissue defects. There were 12 males and 7 females, with an average age of 28.6 years (range, 5-66 years). Etiologies included the post-burn scar in 10 cases, soft-tissue sarcoma in 5 cases, congenital melanocytic nevi in 2 cases, chronic chest wall ulcer in 1 case, and malignant melanoma in 1 case. Defects located in axilla in 8 cases, chest wall in 4 cases, elbow in 5 cases, and shoulder in 2 cases. The area of the defect ranged from 15 cm×3 cm to 20 cm×8 cm. Pre-transfer tissue expansion was used in 11 patients. Thirteen flaps were pedicled with 1 perforator vessel, and 6 flaps were pedicled with 2 perforator vessels. The length of the vascular pedicle was 2.5-4.5 cm, with an average of 3.08 cm. The area of the skin flap ranged from 11 cm×5 cm to 22 cm×10 cm. The flap rotation angle was 110° in 1 case, 120° in 1 case, and 180° in 17 cases. Except for one donor site repaired by skin graft, the other donor sites were directly sutured.ResultsA total of 24 perforating vessels of the brachial artery muscle septum were detected by ICG angiography, 26 were identified during the operation, with an accuracy rate of 92.31%. Eighteen flaps survived without arteriovenous crisis. Venous congestion was observed in the distal 3-cm of one flap and the flap survived after conservative management. Intraoperative analysis showed that the blood perfusion of the distal 4-cm of one flap was poor, the relative value was less than 32%, the flap survived after removing the poor perfusion area. All the patients were followed up 3 to 23 months (mean, 8.6 months). The color and texture of the flap were similar to those of the recipient area. Flap debulking was not needed in all patients owing to the thinness of the flap. The contracture symptoms of patients with scar contracture on the medial of the elbow joint and axilla were significantly improved; a patient with malignant melanoma underwent tumor resection at 1 year and 5 months after operation due to tumor recurrence, and additional surgery was done to remove the recurrent tumor. No tumor recurrence was found in other patients.ConclusionThe ICG angiography technique can be used to explore the perforating vessels of the brachial artery muscle septum. The BAPP flap pedicled with the perforating vessels can be used for the repair of skin and soft tissue defects in the chest wall, axilla, shoulder, and elbow joint.
ObjectiveTo explore the reliability and effectiveness of soft tissue defect reconstruction using the lower trapezius musculocutaneous flap carrying a portion of the latissimus dorsi muscle.MethodsBetween December 2014 and December 2019, 13 patients underwent the reconstruction of soft tissue defects in various sites using the lower trapezius musculocutaneous flap carrying a portion of the latissimus dorsi muscle. There were 10 males and 3 females, with an average age of 52.1 years (range, 29-83 years). Twelve wounds were resulted from resection of various malignant tumor, including 6 cases of head and neck tumors, 5 cases of shoulder and back tumors, 1 case of chest and back tumors. Among the 12 cases, 4 cases were complicated with wound infection and bone exposure, 1 case with skull defect and cerebral dura exposure, and 1 case with wound infection, skull necrosis, and cerebrospinal fluid leakage. One case was injured in a traffic accident, which resulted in infection wound in the back and shoulder and bone exposure. The sizes of the defect and musculocutaneous flap ranged from 11 cm×7 cm to 23 cm×15 cm and 25 cm×8 cm to 40 cm×14 cm, respectively. According to the spatial relationship between the donor and recipient sites, propeller flaps (8 cases) or percutaneous tunnel island flaps (5 cases) were used to transfer the myocutaneous flap to the recipient area to repair the wound. The donor site was directly closed and sutured in 9 cases, and those with excessive tension were repaired with free skin grafts in 2 cases or transferred flaps in 2 cases.ResultsAfter the operation, necrosis of the distal 4-cm of the musculocutaneous flap occurred in 2 cases. After debridement, the resultant wounds were reconstructed using a local flap and a posterior intercostal artery perforator flap, respectively. The remaining 11 myocutaneous flaps survived completely without arteries and veins crisis. The wounds in the donor and recipient areas healed by first intention. All the patients were followed up 1 to 48 months (mean, 7.4 months). The color and texture of the flap were good. During the follow-up, 1 patient underwent tumor resection again due to tumor recurrence, and 1 patient with a scalp hemangiosarcoma died due to unexplained thoracic hemorrhage. Tumor recurrence was not found in the remaining patients. The musculocutaneous flap coverage was stable and the infection was controlled.ConclusionThe lower trapezius musculocutaneous flap carrying a portion of the latissimus dorsi muscle can be an alternation option to reconstruct refractory wounds with exposure of vital structures and organs and infection.
Objective To explore the feasibility and effectiveness of using the superior lateral genicular artery (SLGA) perforator propeller flap to reconstruct soft-tissue defects around the knee joint. Methods Between October 2013 and May 2019, 10 patients underwent repairing of soft-tissue defects around the knee joint using the SLGA perforator propeller flap. There were 6 males and 4 males, with a median age of 34.5 years (range, 6-66 years). Etiologies included radical tumor resection in 4 cases, post-burn scar contracture in 3 cases, post-burn hypertrophic scar in 2 cases, and prothesis exposure after knee arthroplasty in 1 case. Defects located on the lateral knee in 6 cases, proximal lateral leg in 2 cases, popliteal fossa in 1 cases, and infrapatellar region in 1 case. The size of soft-tissue defects was from 6 cm×4 cm to 14 cm×8 cm. The extraction range of the flap was from 10.0 cm×5.5 cm to 23.0 cm×7.0 cm; the length of the perforator pedicle was 2.5-5.0 cm, with an average of 3.65 cm; the flaps were rotated 180°, the large paddle of the propeller flap was used to repair the defect, and the small paddle was used to assist the closure of donor site. Results Blister was observed in the distal 3-cm of one flap and the flap survived after conservative management. All the flaps survived, and the wounds in the donor and recipient areas healed by first intention. There was no vascular crisis, incision dehiscence, infection, or other complications. All 10 patients were followed up 4 to 48 months, with an average of 12.6 months. The color and texture of the flap were similar to those of the recipient area, and there was no need for secondary operation for degreasing and thinning. Scar contracture was corrected; no tumor recurrence was found in tumor patients; the artificial knee joint was preserved, the knee joint flexion and extension activities were good, and all the patient and family members were satisfied with the appearance and function of the lower limbs after operation. Conclusion The SLGA perforator propeller flap surgery is relatively simple without the need of microvascular anastomosis, has the minimal donor-site morbidities, and can provide a compound flap for the repairing of a complex wound. The SLGA perforator propeller flap is one of the optional methods to repair soft-tissue defects around the knee joint.
Objective To explore the reliability and effectiveness of prediction of the pedicle length of the proximally-based anterolateral thigh (pALT) flap which was used to repair the defects following the resection of various malignant tumors using computed tomographic angiography (CTA). Methods The clinical data of 12 patients who met the selection criteria by using pALT flap to repair wounds left after malignant tumor resection between June 2015 and December 2020 were retrospectively analyzed. There were 5 males and 7 females; the age ranged from 16 to 80 years, with an average age of 54.4 years. After tumor resection, the soft tissue defect ranged from 15 cm×5 cm to 30 cm×12 cm; defect sites included 4 cases of lower abdomen, 3 cases of groin, 2 cases of thigh, and 3 cases of buttocks. Preoperative CTA was used to obtain the location information of the descending branch of the lateral femoral circumflex artery and its perforators by maximum density projection, and the length of the pedicle of pALT flap was estimated. Fasciocutaneous flap (5 cases) or myocutaneous flap (7 cases) were cut during operation to repair the defect, and the size of flap ranged from 20 cm×7 cm to 30 cm×12 cm. The donor site of thigh was directly sutured (11 cases) or repaired with skin graft (1 case). Bland-Altman analysis was used to detect the consistency between the pALT flap vascular pedicle length estimated by CTA and the pALT flap vascular pedicle length actually obtained during operation. ResultsOne case had distal blood supply disturbance of the flap and was repaired with skin graft after debridement; the remaining 11 flaps survived. All donor and recipient incisions healed by first intention. All 12 cases were followed up 1-12 months, with an average of 4.3 months. One patient died of pelvic tumor recurrence at 6 months after operation, and no tumor recurrence was found in the other patients. Preoperative CTA estimated that the length of pALT flap vascular pedicle was 9.3-24.7 cm, with an average of 14.7 cm; the actual length of pALT flap vascular pedicle was 9.5-25.0 cm, with an average of 14.8 cm. Bland-Altman analysis showed that there was no significant difference between the pALT flap vascular pedicle length estimated by CTA before operation and the pALT flap vascular pedicle length actually obtained during operation, and the average difference was 0.1 (95% consistency limit: –0.89, 0.74), indicating that they had good consistency. ConclusionCTA can be accurately used to localize the perforator and predict the possible pedicle length of the pALT flap. When performing a pALT flap surgery, preoperative CTA is helpful for surgeons to make a preliminary assessment of the difficult of the operation. The time for exploration of perforators and dissection of the vascular pedicle, and complications can be reduced, and the safety of the operation can be improved.
ObjectiveTo explore the feasibility and technical essentials of soft tissue defect reconstruction following malignant tumor removal of limbs using perforator propeller flaps. MethodBetween July 2008 and July 2015, 19 patients with malignant limb tumor underwent defect reconstruction following tumor removal using the perforator propeller flaps. There were 13 males and 6 females with an average age of 53.4 years (range, 20-82 years). The disease duration ranged from 1 to 420 months (mean, 82 months). The tumors located at the thigh in 10 cases, at the leg in 2 cases, at the arm in 1 case, at the forearm in 1 case, around the knee in 2 cases, and around the elbow joint in 3 cases. Totally 23 flaps (from 8 cm×3 cm to 30 cm×13 cm in size) were used to reconstruct defects (from 4 cm×4 cm to 24 cm×16 cm in size). The potential source arteries included the femoral artery (n=2) , profunda femoral artery (n=3) , superficial circumflex iliac artery (n=1) , lateral circumflex femoral artery (n=6) , superior lateral genicular artery (n=2) , peroneal artery (n=2) , anterior tibial artery (n=1) , brachial artery (n=4) , and radial artery (n=1) . The remaining one was a free style perforator flap. ResultsPartial distal flap necrosis occurred in 3 cases after surgery with rotation angles of 180, 150, and 100° respectively, which were reconstructed after debridement using a free-style perforator flap in 1 case and using free skin grafting in the other 2 cases. The other 20 flaps survived completely after surgery. Primary healing of incisions was obtained at the donor and recipient sites. There was no severe complication such as infection, hematoma, and total flap failure. All patients were followed up 3 months to 5 years (mean, 19 months). One patient with malignant melanoma around the elbow joint had tumor recurrence, and underwent secondary tumor resection. The appearance, texture, and color of the flaps were similar to those at the recipient site. ConclusionsFor patients with malignant tumor of the limb, the perforator propeller flap can be an alternative option for soft tissue defect reconstruction after tumor resection, with the advantages of relatively simple operation and remaining the main vessels.