OBJECTIVETo document the vascular anatomy of the distally based superficial sural artery flap and to study the vascular anastomoses between the superficial sural artery and the septocutaneous perforators of the peroneal artery.

METHODSTen fresh human cadavers were injected with lead oxide, gelatin and water. Twenty lags were then dissected and an overall map of the cutaneous vasculature was constructed. Vascular communications between the superficial sural artery and the lowest septocutaneous perforator of the peroneal artery was evaluated to determine the cutaneous vascular territory of the superficial sural flap. The distally based superficial sural artery island flap was used in 26 cases.

RESULTSThere is constant vascular anastomosis between the superficial sural artery and the lowest septocutaneous perforator of the peroneal artery. The 26 flaps survived uneventfully except for two of partial fat necrosis.

CONCLUSIONThe anatomic information enhances our understanding of flap design.

Blood Vessels ; anatomy & histology ; Cadaver ; Humans ; Leg ; anatomy & histology ; Skin Transplantation ; methods ; Sural Nerve ; anatomy & histology ; Surgery, Plastic ; Surgical Flaps

The medial sural cutaneous nerve (MSCN) and peroneal communicating nerve (PCN) conjoin in the calf area to form the sural nerve (SN). In previous anatomic studies, there was unresolved debate as to the main contributor to the sural nerve, and the relative contributions of MSCN and PCN had not been studied. The purpose of this study is to determine their relative neurophysiologic contributions to the SN by nerve conduction study (NCS). A total of 47 healthy subjects (25 males and 22 females, mean age 29.6+/-10.4 yrs, range 20-59 yrs) participated in the study. This study employed the orthodromic nerve conduction technique: stimulation at the ankle and recording at the mid calf (SN); specifically, we preformed stimulation at the mid calf (MSCN, PCN) and recording at 14cm proximal to the middle of the popliteal fossa (MSCN) and fibular head (PCN). The onset and peak latencies (ms) were SN 2.3+/-0.2 and 3.0+/-0.2; MSCN 2.1+/-0.2 and 2.8+/-0.2; and PCN 2.1+/-0.2 and 2.8+/-0.2. The peak-to-peak amplitudes (micro) and areas (nVsec) of the SN, MSCN, and PCN were 9.7+/-3.9, 7.0+/-4.7, and 5.0+/-3.2; and 7.2+/-2.9, 5.7+/-3.4, and 4.0+/-2.4, respectively. The side-to-side difference was not statistically significant. The main contributor to the SN was found to be the MSCN. The relative contribution ratio of the MSCN to the PCN was 1.37:1 by amplitude and 1.42:1 by area. However, in 32.9% of the subjects, the contribution of the PCN was greater than that of the MSCN.
Sural Nerve/*anatomy & histology/*physiology ; Peroneal Nerve/*anatomy & histology/*physiology ; Neural Conduction/*physiology ; Middle Aged ; Male ; Humans ; Female ; Adult

OBJECTIVETo investigate the anatomical study and clinical applications of sural neuron-myocutaneous flap transposition for repairing the special patients with soft tissue defect in foot and ankle.

METHODSThe branches, distributions and anastomoses of the vessels and nerves lie in superficial layer of the posterior crural region were observed on 30 sides of adult cadaver lower limb specimens perfused with red latex. Since February 2004, distally based sural neuron-myocutaneous flap was applied for repairing 7 cases of soft tissue defect in foot and ankle.

RESULTSThe nutrient vessels of sural nerve, small saphenous vein and posterior femoral cutaneous nerve anastomosed permanently with the musculocutaneous perforators of medial and lateral head of gastrocnemius. There were 2 - 3 anastomoses found respectively. The musculocutaneous perforators pierced the two heads of gastrocnemius muscle (1.8 +/- 0.5) cm medially and (3.7 +/- 0.9) cm laterally away from the groove of the muscle. The medial anastomoses more closed to the middle groove and their diameters were found larger than the lateral ones. In operation, we routinely observed the compound flap for 15 to 20 minutes and found actively errhysis on the muscle, so the fine blood circulation in the flap was demonstrated. All flap survived after operation and the cases were followed up 2 to 6 months with cured osteomyelitis and satisfied flap outline.

CONCLUSIONSDistally based sural neuro-myocutaneous flap can live. The operative method is simple. The flap offers an excellent donor site for repairing the soft tissue defect in foot and ankle in special cases.

Adult ; Female ; Humans ; Male ; Middle Aged ; Popliteal Artery ; anatomy & histology ; Soft Tissue Injuries ; surgery ; Sural Nerve ; anatomy & histology ; surgery ; Surgical Flaps ; blood supply ; innervation

OBJECTIVETo study the distribution of the dominant perforators (the diameter > or = 0.8 mm) of the peroneal artery with color Doppler flow imaging (CDFI) for the purpose of anatomical preparations for the perforator sural neurocutaneous flap.

METHODSThe dominant perforators of the peroneal artery (DPPA) were studied with CDFI on bilateral legs of 20 healthy volunteers. The numbers, diameters and locations of the perforators were recorded for a statistical analysis. From Jan. 2005 to Jan. 2009, 51 free or pedicled sural neurocutaneous flaps supplied by a single DPPA were designed and harvested to repair the defects near the ankle (n=22), at the leg (n=15) and the forefoot or hand dorsum (n=14). The perforators were located preoperatively with CDFI and accuracy of CDFI was evaluated intraoperatively. The causes of false results were analysed to improve examining techniques.

RESULTSThe average number of DPPA was 4.2 with the average diameter of (1.13 +/- 0.24) mm (0.80-1.90 mm). They were located in the second to ninth segment of the line from the fibular caput to the tip of lateral malleolus which was equally divided into nine segments. The largest DPPA was (1.43 +/- 0.29) mm (1.00-1.90 mm) in diameter and most of them were located in the third to fifth segment (80.4%). The average diameter of the lowest DPPA was (1.02 +/- 0.16) mm( 0.80-1.30 mm) and they were located between the sixth to ninth segment. The total 169 DPPA as well as the largest ones mostly appeared in the middle third of the leg. All of the 51 flaps were transplanted successfully without necrosis, and no vascular problems occurred. Preoperative CDFI examination had a 93.6% true-positive rate and an 88.0% positive predictive value. What should be demonstrated was that if just considered the cases after Dec. 2007, the true-positive rate was 97%, and the positive predictive value was 93.9%.

CONCLUSIONSAccording to the distribution characteristics of DPPA, a sural neurocutaneous flap pedicled with one of this relatively large perforator can be designed and harvested to repair skin defects of leg and around ankle, but can not be utilized for that of forefoot. With anastomosis of the perforator, the flap based on the largest DPPA can be used as a free flap to cover defect anywhere. CDFI is reliable in preoperative location of DPPA, which makes the surgical procedures easier.

Adolescent ; Adult ; Aged ; Child ; Child, Preschool ; Female ; Humans ; Leg ; blood supply ; Male ; Middle Aged ; Sural Nerve ; Surgical Flaps ; blood supply ; Tibial Arteries ; anatomy & histology ; diagnostic imaging ; Ultrasonography ; Young Adult