Objective To discuss the feasibil ity of repairing soft tissue defects of lower extremity with a distally based posterior tibial artery perforator cross-bridge flap or a distally based peroneal artery perforator cross-bridge flap. Methods Between August 2007 and February 2010, 15 patients with soft tissue defect of the legs or feet were treated. There were 14 males and 1 female with a mean age of 33.9 years (range, 25-48 years). The injury causes included traffic accident in 8 cases, crush injury by machine in 4 cases, and crush injury by heavy weights in 3 cases. There was a scar (22 cm × 8 cm atsize) left on the ankle after the skin graft in 1 patient (after 35 months of traffic accident). And in the other 14 patients, the defect locations were the ankle in 1 case, the upper part of the lower leg in 1 case, and the lower part of the lower leg in 12 cases; the defect sizes ranged from 8 cm × 6 cm to 26 cm × 15 cm; the mean interval from injury to admission was 14.8 days (range, 4-28 days). Defects were repaired with distally based posterior tibial artery perforator cross-bridge flaps in 9 cases and distally based peroneal artery perforator cross-bridge flaps in 6 cases, and the flap sizes ranged from 10 cm × 8 cm to 28 cm × 17 cm. The donor sites were sutured directly, but a spl it-thickness skin graft was used in the middle part. The pedicles of all flaps were cut at 5-6 weeks postoperatively. Results Distal mild congestion and partial necrosis at the edge of the skin flap occurred in 2 cases and were cured after dressing change, and the other flaps survived. After cutting the pedicles, all flaps survived, and wounds of recipient sites healed by first intention. Incisions of the donor sites healed by first intention, and skin graft survived. Fifteen patients were followed up 7-35 months with an average of 19.5 months. The color and texture of the flaps were similar to these of the reci pient site. According to American Orthopaedic Foot and Ankle Society (AOFAS) ankle and hindfoot score system, the mean score was 87.3 (range, 81-92). Conclusion A distally based posterior tibial artery perforator cross-bridge flap or a distally based peronealartery perforator cross-bridge flap is an optimal alternative for the reconstruction of the serious tissue defect of ontralateral leg or foot because of no microvascular anastomosis necessary, low vascular crisis risk, and high survival rate.
OBJECTIVE: To investigate the clinical results of the medial multiplex flap pedicled with the posterior tibial vessel. METHODS: Twelve cases with soft tissue defects and bone defects of limbs were treated with the medial multiplex flap pedicled with the posterior tibial vessel from September 1992 to May 1999. Among them, bone and soft tissue defects following opened fracture in 7 cases, chronic ulcer following chronic osteomyelitis in 2 cases, melanoepithelioma in 2 cases, bone and soft tissue defects following osteoma resection in 1 case. The bone defect area was from 2.5 cm x 5.0 cm to 4.5 cm x 11.0 cm. Free graft was performed in 5 cases, bridged transposition in 3 cases and reversal transposition in 4 cases, among them, periosteal myocutaneous flap with autogenous or allogeneic bone grafting in 8 cases, myocutaneous flap in 4 cases. The area of the flaps from 6 cm x 8 cm to 12 cm x 25 cm. RESULTS: All flaps were healed by first intention, but in the distal fragments of bigger flaps were partially necrosed in 2 cases. In 10 cases bone healing were obtained after 16 weeks of operation according to the X-ray photos. All cases were followed up from 6 to 18 months. All cases achieved satisfactory result but 1 case died because of lung metastasis of osteoma. CONCLUSION: The multiplex graft pedicled with the posterior tibial vessel is an ideal graft for repairing the large soft tissue defects and bone defects, because it has such advantages as adequate blood supply, big vascular diameter, long pedicle and big dermatomic area.
OBJECTIVE: To provide an anatomical basis for the clinical applications of the medial fascinocutaneous flap of calf and to verify its clinical value. METHODS: In 20 lower limb specimens of adult human cadavers, the number, course, size, position and distribution of septocutaneous branches of the posterior tibial vessels are marked by means of red latex and black ink irrigations through femur artery and septocutaneous branches of the posterior tibial artery respectively. RESULTS: The posterior tibial artery gives off several septocutaneous branches at the upper, middle and lower one-third of the leg respectively. Each septocutaneous artery has one or sometimes two concomitant veins. Based on this result, anterograde or reverse pedicled fasciocutaneous flap can be performed for the purpose of repairing soft tissue defects of leg and foot. The flap was clinically applied to treat leg and foot soft tissue defects in 12 cases with satisfactory results. CONCLUSION: The flap is easy to dissect, the posterior tibial artery can be preserved with high successful rate. Therefore, it offers an useful alternative in the repairing and reconstruction of nonextensive soft tissue defects in the leg and foot.
Tissues defect of the sole of the foot requires a high quality of repair, because the sole bears the body weight most. Once there is loss of soft tissues and skin from the sole, the os calsis and the plantar fascia will be exposed. The use of vascularized tissue flaps to cover the beare area of the sole has been generally recognized. From May, 1985 through May, 1994, 26 cases of extensive tissue defects of the soles were treated. During the primary debridement, the wounds were repaired primarily by using retrograde island skin flap from the medial side of the leg with the posterior tibial artery. From the follwup, the results weresatisfactory. The advantages were: the skin flap had rich blood supply, large skin flap was avallable, the thickness of the flap was appropriate, and the elasticity or the weight bearing was good. Besides, the location of the artery was constant, and the operative technique was easy to handle and could be done in onestage with high survival rate of the skin flap.
ObjectiveTo explore the feasibility and effectiveness of V-Y advanced sense-remained posterior tibial artery perforator flap in repairing wound around the ankle. MethodsBetween March 2012 and January 2015, 11 patients with wounds around the ankle were treated by V-Y advanced sense-remained posterior tibial artery perforator flap. There were 6 males and 5 females with a median age of 37 years (range, 21-56 years). The causes were traffic accident injury in 3 cases, thermal injury in 2 cases, burn in 2 cases, iatrogenic wounds in 2 cases, and local contusion in 2 cases. The disease duration ranged from 1 to 3 weeks (mean, 2 weeks). Injury was located at the medial malleolus in 4 cases, at the lateral malleolus in 3 cases, and at the heel in 4 cases. All had exposure of bone, tendon, or plate. The defect area ranged from 4 cm×2 cm to 5 cm×3 cm; the area of the flap ranged from 11 cm×4 cm to 15 cm×6 cm. ResultsNecrosis of distal flap occurred in 1 case after operation; re-operation to amputate the posterior tibial artery was given and the wound was repaired by proximal skin graft. Light necrosis of distal end was observed in 2 cases, and wound healed at 3 weeks after dressing. And other flaps successfully survived, and primary healing of wounds were obtained. The patients were followed up 6-24 months (mean, 11 months). The flaps were good in color, texture, and appearance. The ankle joint had normal activity. At last follow-up, 10 cases restored fine sense, and 1 case restored protective feeling with posterior tibial artery advanced flap after amputation. ConclusionV-Y advanced sense-remained posterior tibial artery perforator flap has the advantages of reliable blood supply, simple operation, good appearance, and sensory recovery. Therefore, it is an ideal method to repair wound around the ankle.
ObjectiveTo explore the application value of digital subtraction angiography (DSA) in repairing foot and ankle wounds with posterior tibial arterial perforator flaps. MethodsBetween January 2010 and May 2014, 12 cases of foot and ankle wounds were repaired using posterior tibial arterial perforator flaps. There were 7 males and 5 females with an average age of 36 years (range, 22-54 years). The causes were machine injury in 2 cases, falling injury in 3 cases, and traffic accident injury in 7 cases. The disease duration ranged from 7 to 45 days (mean, 16 days). The size of wound ranged from 6 cm×4 cm to 10 cm×5 cm. Preoperative DSA was performed to observe the orientation and distribution of the posterior tibial arterial perforator and the relationship between perforator vessels. Correspondently, the flaps were designed and harvested. The size of flap ranged from 7 cm×5 cm to 11 cm×6 cm. The donor sites were repaired with skin grafts. ResultsPosterior tibial arterial perforator vessels send out ascending branches and descending branches while going down in the superficial layer. All branches were connected to form vertical chain-form anastamosis, and its orientation was consistent with limb vertical axis. According to DSA results, the flaps were designed and harvested easily. All flaps survived after operation. Meanwhile, wounds healed by first intention. All skin grafts at donor site survived. All patients were followed up 6 months. The flaps had good appearance, color, and texture. No ulcer was found. Affected feet had normal walking function. ConclusionThe size, distribution, and chain-form anastamosis condition of the posterior tibial arterial perforator vessels can be accurately observed by DSA, which provides imaging evidence for harvesting posterior tibial arterial perforator flaps and improves the success rate for repairing foot and ankle wounds.
Objective To investigate the clinical application and effectiveness of the composite tissue flaps pedicled with perforating branch of posterior tibial artery for repairing distal leg defects. Methods Between September 2014 and August 2017, 12 patients with skin and bone defects of distal leg were repaired with the composite tissue flaps pedicled with perforating branch of posterior tibial artery. There were 8 males and 4 females with an average age of 41.3 years (range, 25-66 years). The causes of injury included traffic accident injury in 7 cases, heavy crushing injury in 2 cases, tibial osteomyelitis with soft tissue ulcer and necrosis in 2 cases, and bone and soft tissue defect after resection of bone tumor in 1 case. Eight patients underwent primary repair, and 4 patients underwent second-stage repair. The size ranged from 6 cm×4 cm to 10 cm×7 cm in skin flap, from 4.0 cm×2.5 cm to 8.0 cm×6.0 cm in muscle flap, and from 4 cm×2 cm×2 cm to 5 cm×4 cm×4 cm in tibial bone flap. Tibial defects of the donor region were repaired by autologous iliac bone grafting, and the wounds were sutured directly in 7 cases and repaired by autologous skin grafting in 5 cases. Results All composite tissue flaps survived and both the recipient and the donor wounds healed primarily. All patients were followed up 6-12 months, with an average of 10.8 months. The appearance, color, texture of the composite tissue flaps and ankle function were satisfactory. X-ray films showed that the bone flap at the tibia defect and the ilium graft at the donor site both healed well at 6 months after operation. Conclusion The composite tissue flaps pedicled with perforating branch of posterior tibial artery has abundant blood, and it is a good donor region for repairing the distal leg defects combined with circumscribed bone defect.