Objective To investigate the effectiveness of reverse island flaps of digital artery parallel for repairing degloved injuries of the fingerti p. Methods Between June 2008 and January 2010, 13 cases of degloved injuries of the fingertip were treated. There were 8 males and 5 females with an average age of 34 years (range, 19-62 years). The causes of injuries were as follow: impact and press injury in 5 cases, wringer injury in 7 cases, and crush injury in 1 case. The injured fingers were comprised of index finger in 6 cases, middle finger in 4 cases, ring finger in 2 cases, and l ittle finger in 1 case. The size of skin and soft tissue defect ranged from 2.0 cm × 1.8 cm to 3.0 cm × 2.5 cm. Three cases compl icated by fracture of thedistal phalanx, 1 case by rupture of the insertion of extensor tendon, and 1 case by rupture of the insertion of flexor tendon. The average time from injure to surgery was 4 hours (range, 1 hour and 30 minutes-12 hours). Two neighboring skin flaps located in the same course of digital artery were adopted to repair defect of the fingertip. The size of proximal skin flap ranged from 1.2 cm × 1.0 cm to 2.0 cm × 1.5 cm and the size of distal skin flap ranged from 1.1 cm × 1.0 cm to 1.5 cm × 1.3 cm. The free skin grafts were used to repair the donor sites. Results Circulation crisis occurred in 1 case at 2 hours after operation and was el iminated by interval disconnecting. The other flaps and skin grafts survived and the wounds healed by first intention. The patients were followed up 6-18 months (mean, 10 months). All flaps presented the satisfactory appearance and texture, and the flexion and extension function of wounded fingers recovered to normal. Two-point discrimination ranged from 7 to 11 mm at last follow-up. According to the functional assessment criteria of upper l imb formulated by the Hand Surgery Branch of Chinese Medical Association, the results were excellent in 9 cases, good in 3 cases, and fair in 1 case with an excellent and good rate of 92.3%. Conclusion Based on the anatomical features of communicating branches of distal interphalangeal joint, two neighboring flaps located in the same course of digital artery are adopted to repair soft tissue defect of the fingertip. This surgical method is a simple and effective method.
OBJECTIVE: To provide anatomical bases for dorso-ulnar aspect of mid-hand reverse flap. METHODS: After red latex was infused into the arteries of 40 sides of adult cadava upper limbs, the origin, course, branches, distribution and distal anastomosis on the dorsal carpal branch of ulnar arteries were observed. And the mid-hand flap transfer was used to repair two cases of soft tissue defect (ranged 4.5-5.0 cm x 2.0-3.5 cm on ring and little fingers). RESULTS: The dorsal carpal branch begins with ulnar artery (3.9 +/- 1.2) cm above the pisiform with diameter of (1.3 +/- 0.2) mm, and branches off into ascending and descending branches. The descending one is the continuing of dorsal branch, it crosses the ulnar edge of the fifth metecarpal bone and anastomizes with the digital artery of little finger or hypothenar branch of deep palmar (accounted for 70%). While the other ascending branch with the former two branches formed anastomosis accounts for 30%. The two cases got healed in one-stage. The function of fingers recovered after 3-4 month follow-up. CONCLUSION: The reverse flap of dorso-ulnar aspect of mid-hand is available to repair the soft tissue defect on dorsum of hand with neighbor finger.
The skin and soft tissue defects or ulceration of the wight-bearing part of the sole was difficult to repair with medial plantar island flap, but would be treated with retrograde island flap carrying plantar metatarsal arteries as pedicle. Ten flaps were applied in 9 patients. They had either indolent ulcer or skin defect secondary to excision of painful corn or callosities of the front part of the sole. The flaps were 3 cm to 5 cm long and 3 cm to 4 cm wide, and they all survived following retrograde transfer. The patients were followed up for 1 to 10 years. It was found that the patients could bear weight on the operated foot and could walk without pain or lameness. The flaps were resistant to abrasion from long-time walking. It was concluded that this kind of flap was best suitable to repair the ulcers and defects over the front part of the sole despite there were some minor shortcomings such as the size of the flaps available was small and the donor site required split skin graft for coverage.
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.
ObjectiveTo discuss the effectiveness of improved interosseous dorsal artery reversed island flap to repair dorsal skin and soft tissue defect of the hand. MethodsBetween March 2009 and September 2012, 29 cases of dorsal skin and soft tissue defects were treated with improved interosseous dorsal artery reversed island flap. Of 29 cases, there were 17 males and 12 females, aged 23-71 years (mean, 47 years); and the left hand was involved in 12 cases and the right hand in 17 cases. There were 11 cases of avulsion injury, 9 cases of crushing injury, 5 cases of strangulation injury, and 2 cases of traffic accident injury; the interval of injury and admission was 1-7 hours (mean, 4 hours). Two patients had scar contracture. The locations of soft tissue defects were dorsal hands in 21 cases, first webs in 5 cases, and dorsal thumb in 3 cases. The size of soft tissue defects ranged from 4 cm×3 cm to 10 cm×8 cm. One-stage repair was performed in 11 cases, and two-stage repair in 18 cases. The size of flaps ranged from 5.5 cm×4.5 cm to 12.0 cm×10.0 cm. The donor sites were sutured directly or repaired by skin grafting. ResultsAll flaps survived, and wounds healed in first stage. And the grafted skins at donor sites all survived, and incisions all healed in first stage. Twenty-six patients were followed up 3 months-3 years (mean, 19.5 months). Bulky flap was observed in 3 cases, and defatted operation was performed after 6 months; the other flaps had good appearance and texture, and wrist function was normal. According to total angle of motion (TAM) systematic evaluation, the results were excellent in 17 cases, good in 6 cases, and fair in 3 cases at 3 months after operation. ConclusionImproved interosseous dorsal artery reversed island flap has the advantages of easy-to-obtain, simple operation, and high survival rate of flaps, so it is an effective method to repair dorsal skin and soft tissue defect of the hand.
Objective To investigate the venous drainage in retrograde island flaps by fluorescence tracing technique and to observe the pathway of venous drainage. Methods The 0.1mL venous blood was collected from the marginal ear vein of every rabbit (n=20), respectively, and erythrocytes were separated by centrifugation and then were labeled with FITC. Positive rate and fluorescence intensity of FITC-labeled RBC were detected by flow cytometry. RBC morphous was observed under the inverted fluorescence microscope. Saphenous retrograde island fasciocutaneous flap and antegrade islandfasciocutaneous flap (4.0 cm × 3.0 cm in size with vascular pedicle length of 3.0 cm) were successfully establ ished in hind l imbs of 20 New Zealand white rabbits.One hind l imb of each rabbit was randomly assigned as the experimental group and the contralateral side was assigned as the control. The same flap was establ ished in the control group without any fluorescence tracer. According to retrograde or antegrade flaps, the experimental group was divided into 2 groups with 10 rabbits in each group. And then, according to different pathways of tracer-giving, each group was divided into 2 subgroups of artery and vein, with 5 rabbits in each subgroup. The labeled erythrocytes (5 μL) were injected into artery or vein and then flaps were cut down 5 seconds later. The flaps were immediately frozen and chipped (5-7 μm). Consecutive three frozen sections were made and two of them were stained with HE and GENMED, respectively, but the third one was squashed without staining. All frozen sections were observed under the microscope. Results Positive rate of FITC-labeled RBC was beyond 99% and fluorescence intensity was more than or equal to 103. FITC-labeled RBC showed steady green fluorescence under the inverted fluorescence microscope. Fluorescence appeared in all experimental groups, but none was found in the control groups. In antegrade island flap group, fluorescence appeared mainly in lumen of vein, wall of vein and inner membrane and outer membrane of artery. In retrograde island flap group, fluorescence distributed principally in inner membrane and outer membrane of artery and wall of vein. Conclusion The fluorescence tracing is appl icable to the research of venous drainage. Venous drainage in the antegrade island flaps is mainly through lumen of vein, wall of vein and inner membrane and outer membrane of artery. While, venous drainage in retrograde island flaps is principally through inner membrane and outer membrane of artery and wall of vein.