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 provide an ideal method for repairing the circular cicatricial contracture of thigh. METHODS: Deep inferior epigastric perforator (DIEP) island flaps was elevated based only on the deep inferior epigastric artery and vein and transferred to cover the thigh wound after scar had been resected. RESULTS: Four DIEP island flaps was applied clinically and all flaps survived. The size of the flaps ranged from (8 cm x 28 cm) to (11 cm x 32 cm). Venous return and edema had been obviously improved postoperatively. There was no abdominal weakness and hernia in the donor sites. CONCLUSION: DIEP flap not only retains the advantages of TRAM flap such as good blood supply and rich tissue volume, but also preserves the integrity of the rectus abdominis muscle. DIEP island flap is a good material for repair of the circular cicatricial contracture of the thigh.
To introduce a new technique for vascular pedicle elongation in the anterolateral thigh island flap transplantation and evaluate the outcome of this technique in the clinical application. Methods From January 2003 to January 2006, 6 patients (5 males, 1 female; age, 1849 years) were admitted for surgical operation because of the soft tissue defect around the knee joint. The soft tissue defect after the injury was found in 3 patients, the defect after the removal of the softtissue tumor in 1, and the defect after the prosthetic replacement in the knee joint in 2. The soft tissue defects ranged in size of 8 cm×4 cm to 15 cm ×6 cm. When the anterolateral island flap of the thigh underwent the reverse transplantation, the ascending branch of the lateral circumflex femoral artery was used as a nutrient vessel for the flap, and the descending branch of the lateral circumflex femoralartery was separated to the distal part. The main trunk of the lateral circumflex femoral artery was ligated at the point that was proximal to the furcation ofthe ascending and decending branches so that the vessel pedicle of the flap could be lengthened and then the defect was repaired.The flaps ranged in size of 10cm×6 cm to 18 cm×8 cm Results All the flaps were successfullytransferred in the 6 patients. The lengthened pedicle ranged in length from 8 to 12 cm, with an average of 10 cm. There was no vascular crisis after operation. All the transferred flaps survived, with a color and texture similar to those in the recipient site. The postoperative followup for 6-18 months revealed that the motion range of the knees was satisfactory. Conclusion The vascular pedicle elongation technique can enlarge the application scope of the anterolateral thigh island flap and the survival rate of the flap is not influenced by any factor.
Objective To investigate the feasibility of reconstruction of the contracted eye socket by an application of the expanded forehead island skin flap with the supratrochlear and supraorbital arteries. Methods From June 2002 to June 2005, 6 patients with the eye socket defects were treated with an expanded forehead island skin flap with the supratrochlear and supraorbital arteries.There were 4 males and 2 females, aged 16-42 years. The defects were caused bytumors in 2 patients, by trauma in 3, and by chemical burns in 1; the defects were in the left eyes of 4 patients and in the right eyes of the remaining 2 patients, with the illness course of 1 year to 4 years.All the patients first underwent the skin and soft tissue expanding operation on the donor forehead skin area; 1 month later, the transplant of the expanded forehead island skin flap with the supratrochlear and supraorbital arteries was performed to reconstruct the eye sockets. The flaps ranged in size from 8 cm×5 cm to 10 cm×6 cm.The appearance and functional recovery of the reconstructed eye sockets were observed after operation. Results The follow-up of all the patients for 1-3 years revealed that the skin flaps survived, with no visible contracture, and the fine sensory function was still present. The artificial eyes could be steadily placed in the reconstructed eye sockets. The donor areas were healed with no visible hyperplastic scars. Conclusion Reconstruction of the eye socket with an expanded forehead island skin flap with the supratrochlear and supraorbital arteries is a feasible, effective and simply method, and the patient can have a concealed incision, a satisfactory appearance, and a fine sensory function.
Objective To investigate the procedure and applications ofantegrade and retrograde dorsal metacarpal flaps with cutaneous branches as pedicles in repairing soft tissue defects of wrist and fingers. Methods From 1995 to 2003, we observed that the proximal and distal branches, deriving from the dorsal metacarpal artery, formed a consistent anastomosis arc subdermally. The anastomosis arc was paralleled to the dorsal metacarpal artery. Antegrade and retrograde dorsal metacarpal flaps could be designed using proximal anddistal branches as pedicles. Twenty-seven cases of soft tissue defects were treated by use of dorsal metacarpal flaps with cutaneous branches as pedicles, including 3 cases of defects on dorsum of hand with antegrade flaps, and 24 cases of defects on fingers with retrograde flaps ( index finger:12 cases; middle finger: 6 cases; ring finger: 4 cases; and little finger:2 cases). The dimensions of the antegrade flaps were 2.0 cm×4.0 cm~4.0 cm×6.0 cm, and the dimensions of theretrograde flaps were 2.5 cm×3.5 cm~3.0 cm×7.0 cm.The incision of the donor site was closed directly. Results All flaps survived. After a follow-up of 13 years, the texture and color of the flaps were good, and the shape and function of the donors were normal. Conclusion The antegrade or retrograde flap pedicled with the distal or proximal cutaneous branches of thedorsal metacarpal artery, is an optimal flap in repairing finger or wrist softtissue defects.
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.