Objective To investigate the clinical significance of the distally-based sural musculocutaneous flap for the treatment of chronic calcaneal osteomyelitis. Methods From January 2002 to October 2005, 7 patients (4 males, 3 females; age range, 15-68 years ) were treated with the distallybased sural musculocutaneous flap, who had chronic calcanealosteomyelitis after calcaneal fracture. After the radical debridement for all the nonviable and poorly vascularized tissues, all the chronic calcaneal osteomyelitis patients, who had suffered from open calcaneal fracture or closed calcaneal fracture, were treated with the open reduction, the internal fixation, and thebone graft. The ulcer lasted for 3-12 months before diagnosis of osteomyelitis. The musculocutaneous flaps ranged in size from 8 cm×4 cm to 12 cm×7 cmand the muscle flaps ranged from 4 cm×3 cm to 6 cm×5 cm. The donor defects were closed primarily in 5 patients and were resurfaced with the splitthicknessskin graft in 2 patients. Results All the musculocutaneous flaps survived completely and all the wounds healed smoothly. All the patients followed up for 2-6 months had no recurrence of osteomyelitis or return to their preoperative ambulatory status.Conclusion It is feasible to use the distallybased sural musculocutaneous flap for treatment of chronic calcaneal osteomyelitis.
Objective To investigate the anatomic foundation of using main branch of posterior femoral nerve to restore the sensation function of distal basedsural island flap. Methods Thirty cases of adult human cadaver legs fixed by 4%formaldehyde were used. Anatomical investigation of the posterior femoral nerves of lower legs was conducted under surgical microscope to observe their distribution, branches and their relationship with small saphenous vein. Nerve brancheswith diameter more than 0.1 mm were dissected and accounted during observation.The length and diameter of the nerves were measured. Results The main branch of posterior femoral nerve ran downwards from popliteal fossa within superficial fascia along with small saphenous vein. 70% of the main branch of the posterior femoral nerves lay medially to small saphenous vein, and 30% laterally. They wereclassified into 3 types according to their distribution in lower legs: typeⅠ (33.3%) innervated the upper 1/4 region of lower leg (region Ⅰ), type Ⅱ (43.3%) had branches in upper 1/2 region (region Ⅰ and Ⅱ), and type Ⅲ (23.3%) distributed over the upper 3/4 region (region Ⅰ, Ⅱ and Ⅲ). In type Ⅱ, the diameter of the main branches of posterior femoral nerves in the middle of popliteal tossa was 10±04 mm and innervated the posterior upper-middle region (which was the ordirary donor region of distal based sural island flaps) of lower legs with 2.0±0.8 branches, whose diameter was 0.3±0.2 mm and length was 3.5±2.7 mm. The distance between the end of these branches and small saphenous vein was 0.8±0.6 mm. In type Ⅲ, their diameter was 1.2±0.3 mm and innervated the posterior upper-middle region of lower legs with 3.7±1.7 branches, whose diameter was 0.4±0.1 mm and length was 3.7±2.6 mm. The distancebetween the end of these branches and small saphenous vein was 0.8±0.4 mm. Conclusion 66.6% of human main branch of posteriorfemoral nerves (type Ⅱ and type Ⅲ) can be used to restore the sensation of distal based sural island flap through anastomosis with sensor nerve stump of footduring operation.
Objective To investigate the clinical efficiency of thedistally based sural island flap and myofasciocutaneous flap in reconstruction of defect and osteomyelitic cavity of the ankle and foot. Methods From June 1997 to October 2004, 21 patients with soft tissue defects and osteomyelitis in the ankle and foot were treated with the distally based sural island flap and myofasciocutaneous flap. There were 20 males and 1 female aging from 6 to 78 years. The defect was caused by soft tissue defect trauma(18 cases) and electrical injury ( 3 cases). Among 21 patients, 17 were treated with island flaps, 4 by the myofasciocutaneous flap. The size of flaps ranged from 4 cm×5cm to 16 cm×22 cm. The donorsites were closed directly in 4 cases. Results The flaps completely survived in 21 cases and healing by first intention was achieved. After a follow-up of 36 months, no complication occurred. The color and texture of the flaps were good. The appearance and the function were satisfactory. Conclusion Distally basedsural flap is a reliable flap. This flap has rich blood supply without sacrifice of major arteries. Flap elevation is easy. It is very useful in repairing large soft tissue defects of the lower leg, the ankle and the foot, especially inrepairing deep soft tissue defects and osteomyelitic cavities .
Objective To explore the application of the improved operative technique and clinical results of sural nerve nutritional vessel axial flap repairing the soft tissue defects of the lower leg,the ankle and the foot. Methods From January 1999 to Novenber 2004,the modified flaps were applied in 22 cases of soft tissue defect on the basis of anatomy of the intermusclar septum perforating branches of peroneal artery and the sural nerve nutritional vessel.There were 14 males and 8 females. Their ages ranged from 5 to 54 years.According to the position and size of the soft tissue defects, the sural nerve nutritional vessel flap pedicled with the perforating branch of the peroneal artery in the lower leg were desingned and obtained to repair the soft tissue defects of the lower leg,the ankle and the foot.The flap size ranged from 13cm×12cm to 30cm×20cm. The vessel pedicle of perforating branches ranged from 1.7cm to 3cm.The distribution of the vessel pedicle of perforating branches ranged from4.5cm to 8cm on the lateral malleolus.The diameters of vessel ranged from 1mm to 1.2mm. Results The flap pedicle with the terminal branch of the peroneal artery was used in 13 cases, the other branches were used in 9 cases. Among of 22 cases,the sural nerve were anastomosed with the acceptor sensory nerve in 4 cases. The skin sense were satisfactory after 1 year of operationnd 2-point discrimination was 10-13mm. All flaps survived completely in 22 cases. The outline andfunction were satisfactory during 6-18 months follow-up. Conclusion The blood supply of this flap is reliable. Flap elevation is easy. The size of flap is large enough to repair skin defects of the lower leg, the ankle and the foot.
Objective To investigate the origin of small saphenous vein of distally-based of sural nerve nutrient vessels flap and its clinical application. Methods The origins of nutrient vessels of small saphenousvein and communicating branches of superficial-deep vein were observed on specimens of 30 adult cadaveric low limbs by perfusing red gelatin to dissect the artery. Results The nutrient vessels of small saphenous vein originated from the heel lateral artery, the terminal perforator branches of peroneal artery and intermuscular septum perforating branches of peroneal artery. There were 2 to 5 branches ofsuch distally-based perforating branches whose diameters ranged from 0.6 to 1.0 mm. Those perforating branches included fascia branches, cutaneous branches nerve and vein nutrient branches. Those nutrient vessels formed a longitudinalvessel chain of sural nerve shaft, vessel chain of vein side and vessel networkof deep superficial fascia. The small saphenous vein had 1 to 2 communicating branches of superficial-deep vein whose diameter was 1.7±0.5 mm, 3.4±0.9 cm to the level of cusp of lateral malleolus, and converged into the fibular vein. Conclusion Distally-based sural nerve, small saphenous vein, and nutrient vessles of fascia skin have the same region. The communicating branches of superficial-deep vein is 3 to 4 cm to the level of cusp lateral malleolus. These communicating branches could improve the venousdrainage of the flap.
Objective To investigate the distribution of the perforating branches artery of distally-based flap of sural nerve nutrient vessels and its clinical application. Methods The origins and distribution of perforating branchesartery of distally-based flap were observed on specimens of 30 adult cadavericlow limbs by perfusing red gelatin to dissect the artery.Among the 36 cases, there were 21 males, 15 females. Their ages ranged from 6 to 66, 35.2 in average. The defect area was 3.5 cm×2.5 cm to 17.0 cm×11.0 cm. The flap taken ranged from 4 cm×3 cm to 18 cm×12 cm. Results The perforating branches artery of distally-based flap had 2 to 5 branches and originated from the heel lateral artery, the terminal perforating branches of peroneal artery(diameters were 0.6±0.2 mm and 0.8±0.2 mm, 1.0±1.3 cm and 2.8±1.0 cm to the level of cusp lateral malleolus cusp).The intermuscular septum perforating branches of peroneal artery had 0 to 3 branches. Their rate of presence was 96.7%,66.7% and 20.0% respectively(the diameters were 0.9±0.3, 1.0±0.2 and 0.8±0.4 mm, andtheir distances to the level of cusp of lateral malleolus were 5.3±2.1, 6.8±2.8 and 7.0±4.0 cm). Those perforating branches included fascia branches, cutaneous branches, nerve and vein nutrient branches. Those nutrient vessels formed longitudinal vessel chain of sural nerve shaft, vessel chain of vein side and vessel network of deep superficial fascia. The distally-based superficial sural artery island flap was used in 18 cases, all flaps survived. Conclusion Distally-based sural nerve, small saphenous vein, and nutrient vessels of fascia skin have the same origin. Rotation point of flap is 3.0 cm to the cusp of lateral malleolus, when the distally-based flap is pedicled with the terminal branch of peroneal artery.Rotation point of flap is close to the cusp of lateral malleolus, when the distally-based flap is pedicled with the heel lateral artery.
OBJECTIVE: To sum up the application experience of the sural nerve island flap pedicled with the collateral vessels. METHODS: From 1997, the retrograde-flow sural nerve island flaps pedicled with collateral vessels were performed to repair the soft tissues defects of the shank in 3 cases, ankle in 3 cases and foot in 8 cases. RESULTS: Twelve flaps were survived, one flap was partially necrosed and one flap was necrosed. Among them, 10 wounds healed by first intention, 3 cases were healed after changing dressing and the one necrosed flap was repaired by free flap transplantation. Nine cases were followed up for 3 to 21 months and had fine appearance and function. The flap texture was similar to normal skin, the sensation of flap partially recovered after 6 months. CONCLUSION: The flap has more reliable blood supply and great rotation arc, it is easy to resect with little injury. It is excellent for repairing the soft tissues defect in the anterior leg, ankle and proximal half of foot. It is more significant while the main blood vessels are damaged.
ObjectiveTo assess the effectiveness of the sural fasciomyocutaneous perforator flap in repair of soft tissue defect in weight-bearing area of the foot. MethodsBetween January 2007 and September 2010, 19 patients with soft tissue defects in the weight-bearing area of the foot were treated with sural fasciomyocutaneous perforator flaps. The etiology was traffic accident in 16 patients and crush injury in 3 patients. The interval of injury and admission was 2 hours to 14 days. The size of defect ranged from 8 cm×6 cm to 26 cm×16 cm; the size of flap ranged from 7 cm×7 cm to 25 cm×12 cm. The donor sites were repaired by free skin graft. The flap survival was observed after operation, and the pain score and sensory recovery at the reci pient site were used to assess the effectiveness. ResultsThe flaps survived with satisfactory aesthetic and functional results in 18 cases. Partial flap necrosis was noted and second healing was achieved after spl it thickness skin grafting in 1 case. One case of delayed ulceration was also noted after 5 weeks, ulceration was successfully cured after wound care and avoidance of weightbearing for 2 weeks. All patients were followed up 9-25 months (mean, 14.1 months). The flaps had good appearance, without bulky pedicle. Superficial sensation and deep sensation were restored in 17 cases (89.4%) and 18 cases (94.7%) respectively at last follow-up. ConclusionSural fasciomyocutaneous perforator flap is a rel iable modality in heel reconstruction, having the advantages of low ulceration rate, good wear resistance, and good sensation recovery.