Objective To explore the effectiveness of changeable cross-leg style sural neurovascular flap in repairing contralateral fairly large soft tissue defects on dorsum of forefoot. Methods Between June 2006 and June 2015, 12 patients with fairly large soft tissue defect on dorsum of forefoot were treated. There were 8 males and 4 females, with an average age of 35.6 years (range, 18-57 years). Defects were caused by traffic accident injury in 4 cases, machine crush injury in 3 cases, and heavy object crush injury in 3 cases, with a median disease duration of 11 days (range, 5 hours to 28 days) in the 10 cases; the defect cause was atrophic scar in 2 cases, with disease duration of 2 years and 3 years respectively. The wound size of soft tissue ranged from 6.2 cm×4.1 cm to 11.5 cm×7.4 cm; combined injuries included tendon exposure in all cases and bone exposure in 6 cases. The changeable cross-leg style sural neurovascular flaps were used to repair defects. The width and length of flap pedicle were increased. The cross-leg position was maintained with the elastic net bandage. The size of flaps was 16 cm×7 cm to 21 cm×11 cm, with a pedicle of 8-16 cm in length and 5-6 cm in width. Results After operation, 10 flaps survived, and wound healed by first intention. Extravasated blood occurred at the flap edge in 2 cases and was cured after symptomatic treatment. No pressure sore occurred. All patients were followed up 3-24 months (mean, 7 months). The appearance and function of the affected legs were good, and the flaps had soft texture and normal color. Conclusion Changeable cross-leg style sural neurovascular flap can achieve good effectiveness in repairing fairly large soft tissue defect on dorsum of forefoot. Some drawbacks of single cross-leg style can be avoided.
Objective To provide the anatomical basis for posterior femoral neurocutaneous vascular flap pedicled with direct popliteal artery perforator. Methods A total of 30 embalmed lower limbs of adult cadavers perfused with red latex were dissected and measured to observe the course and distribution of posterior femoral cutaneous nerve (PFCN), and the anastomoses between direct popliteal artery perforator and nutrient vessels of PFCN. Mimic operation was performed on 1 side of fresh specimen. Results PFCN started from the midpoint of the inferior gluteus maximus edge, and went down along the middle line of posterior thigh region, and the final trunk of PFCN accompanied with small saphenous vein down to the middle line of lower leg. The diameters of PFCN was (3.0 ± 0.6) mm at the inferior gluteus maximus edge, and was (2.0 ± 0.7) mm at the superior fossa poplitea. The nutrient vessels of PFCN were multi-segmental and polyphyletic. The direct popliteal artery perforator which started from popliteal artery directly was constant pierced into deep fascia about 7-11 cm above the knee joint, and its original diameter was (0.8 ± 0.2) mm. The direct popliteal artery perforator had 1-2 accompanying veins, and this perforator artery was the main nutrient vessel of the inferior segment of PFCN. The direct popliteal artery perforator gave off 5-8 small vessels which anastomosed with the 1st-3rd perforator of deep femoral artery, the obturator artery perforator, and the lateral femoral circumflex artery perforators. Then these nutrient vessels formed vascular plexus along PFCN in the middle line of posterior region of thigh. Mimic operation showed that the posterior femoral neurocutaneous vascular flap pedicled with direct poplitea artery perforator could be formed successfully. Conclusion The posterior femoral neurocutaneous vascular flap pedicled with direct popliteal artery perforator has constant blood supply and can be easily formed to repair defects around knee joint.
Objective To provide the anatomic basis for thedesign of the intermediate dorsal neurocutaneous flap on the foot and to reportthe clinical results. Methods On 32 adult cadaver lower limb specimens perfused with red latex, the origins, diameters, courses, branches, and distributions of the intermediate dorsal cutaneous nerve of the foot and its nutrient vessels were observed. On this anatomic basis, from June 2004 to October2005, 5 flaps were developed and applied to the repair of the soft tissue defect in the feet of 4 patients. Results The intermediate dorsal cutaneous nerve of the foot was found to arise from the superficial peroneal nerve. Crossing the intermalleolar line, it was located 1.3±0.6 cm lateral to the midpoint of the line with a diameter of 2.05±0.56 mm. The nerve stem divided into branches 2.8±1.3 cm distal to the line. They distributed the dorsal skin of the second, third and fourth metatarsal and toe. On average, 5.1 perforators per specimen were identified. At least 3 nutrient vessels were always found in each. They originated from the cutaneous branches of the anterior tibial artery and the dorsalis pedis artery in the proximal end and the dorsalis metatarsal artery in the distal end. They perforated the deep fascia 4.3±0.4 cm proximal to the intermalleolar, 1.6±0.3 cm proximal to the tip of the third toe webspace and 1.5±0.3 cm proximal to the tip of the forth toe webspace, respectively. The external diameters of them were 0.82±0.13, 0.42±0.07 and 0.49±0.09 mm, respectively. The patients were followed up for 4-10 months. All theflaps survived completely. Their appearance and function were satisfactory. Conclusion The distallybased intermediate dorsal neurocutaneousflap on the foot has an abundant blood supply. This kind of flap is especially useful in repair of the soft tissue defect in the foot.
Objective To investigate the management of the soft tissue defect after the Achilles tendon repair. Methods From April 1996 to April 2006, 24 patients(17 males, 7 females; aged 16-59 years), who suffered from postoperative Achilles tendon exposure caused by local soft-tissue necrosis after the Achilles tendon repair, were treated and evaluated. Of the 24patients, 8 had an original open injury (machinecrush injury in 2 patients, heavy-object press injury in 3, motorcycle wheel crush injury in 3) and 16 patients had a closed injury (sports injury). In their treatment, the transferof the sural neurovascular flap was performed on 8 patients and the transfer ofthe saphenous neurovascular flap was performed on 3 patients. The secondary Achilles tendon repair was performed on 13 patients before the neurovascular flap transfer was performed. The time between the injury and the operation was 9-76 days, and the time between the Achilles tendon expousure and the operation was 3-65 days. Results All the flaps survived and the Achilles tendon exposure was well covered by the flaps of good texture. Eighteen patients followed up for 6 months to 24 months had no flap complication, and the two point discrimination of the flaps was 12-20 mm. The AOFASAnkleHindfoot Scale assessment revealed that 8 patients had an excellent result, 6 had a good result, 3 had a fair result, and just 1 had a poor result, with theexcellent and good results accounting for 77.8%. Sixteen patients (89%) were able toperform a tip-toe stance on their operative sides, and only 3 of them complained a loss of plantarflexion strength. However, 2 patients still could not perform the tip-toe stance. Conclusion The Achilles tendon repair, ifnot well performed, can result in the local soft-tissue necrosis and the subsequent Achilles tendon exposure. If those complications occur, the neurovascular flap transfer should be performed as soon as possible; if necessary, the secondary Achilles tendon repair should be performed, too.
【Abstract】 Objective To investigate the operative techniques and cl inical results of repairing the soft tissue defectsof forearm and hand with free peroneal perforator-based sural neurofasciocutaneous flap. Methods From May 2006 toJanuary 2007, 6 patients including 5 males and 1 female were treated. Their ages ranged from 22 years to 51 years. They were injured by motor vehicle accidents (2 cases), or crushed by machines (4 cases), with skin defect of hand in 1 case, skin defect of hand associated with tendon injuries and metacarpal fractures in 2 cases, skin defect of forearm in 2 cases, and forearm skin defects with fractures of radius and ulna in 1 case. The areas of soft tissue defect ranged from 16 cm × 7 cm to 24 cm × 10 cm. The debridement and the primary treatment to tendons or bones were performed on emergency. And free flaps were transplanted when the wound areas were stable at 4 to 7 days after the emergent treatment. During the operation, the flaps were designed along the axis of the sural nerve nutrient vessels according to the shape and size of the soft tissue defects, with the peroneal perforator above the lateral malleolus as the pedicle and along with a part of the peroneal artery for vascula anastomosis. Then the flaps were harvested and transferred to the reci pient sites with the peroneal vartey anastomosed to the radial (or ulnar) artery and the peroneal veins to one of the radial (or ulnar) veins and the cephal ic vein, respectively. The flap size ranged from 18 cm × 8 cm to 25 cm × 12 cm. The donor areas were closed by skin grafts. Results The 5 flaps survived after the surgery. Partial inadequate venous return and distal superficial necrosis happened in only 1 case, which also got secondary heal ing by changing dressing and anti-infective therapy. The donor sites reached primary heal ing completely. The followed-up in all the patients for 6 to 13 months revealed that the appearance and function of the flaps were all satisfactory, and no influence on ambulation of donor site was found. Conclusion Peroneal perforator-based sural neurofasciocutaneous flap has the advantages of favourable appearance, constant vascular pedicle, rel iable blood supply, large size of elevation and minor influence on the donor site. And the free transfer of this flap is an ideal procedure to repair the large soft tissue defects of forearm and hand.
Objective To establ ish the experimental animal model of perforator sural neurocutaneous flap for laying a foundation of further study on its physiology and haemodynamics. Methods Thirty-five New Zealand rabbits were divided into four groups, weighing 2.5-3.0 kg and being male or female. In group A (n=5), vivisection was performed to observe thestarting point and arrangement of sural nerve, its concomitant vessels, posterior tibial artery and perforating vessel. In groups B and C (n=5), red latex and gelatin-lead oxide were injected into the concomitant arteries of sural nerve and the posterior tibial arteries respectively to observe their arrangement, the diameter and anatomasis. In group D, forty neurocutaneous flaps based on single perforator were elevated in the twenty rabbits with a size of 7 cm × 1 cm and a pedicle of 0.5 cm. The colour and condition of flaps were observed. Results The sural nerve originated from posterior tibial nerve, passed through the lateral head of the gastrocnemius at site of the popl iteal fossa, descended obl iquely to exterior, entered in the deep fascia at about (5.42 ± 0.15) cm above lateral malleolus, and descended vertically to lateral malleolus. Its concomitant artery originated from deep femoral artery with an initial diameter of (0.73 ± 0.11) mm and extended to the lateral malleolus along the sural nerve. A perforating branch of posterior tibial artery at the position of the calcaneus originated from the midpoint of the l ine connecting between the medial malleolus and the calcaneus with an initial diameter of (0.45 ± 0.01) mm. The perforating branch traversed the calcaneus to the region of the lateral malleolus, and anastomosed to the concomitant artery of the sural nerve, forming a vascular plexus around the sural nerve. In group D, two cases were excluded due to infection. The survival rate was 78.0% ± 1.5% in other 38 flaps 10days after operation. Conclusion The perforator based sural neurocutaneous flap in rabbit is a good experimental model,which has stable anamatic features and rel iable blood distribution.