Objective To present a method for quantifying the anastomosis between two vessels based on angiograpy and provide a theoretical basis for vascular study in skin flap. Methods Ten bilateral skin flaps of 20 cm×20 cmbased on deep iliac circumflex vessels were elevated fromthe abdominal wall including musculus rectus abdominis and deep superior epigastric vessels in 5 minipigs which were 100-115 cm in length and 25-35 kg in weight. One side was inserted an expander under the panniculus carnosus and was expanded regularly with 30-40 ml isotonic Na chloride injection (expanded group) and the other was unexpanded group which were without any treatment. A X-ray image of the flap vessles was obtained after a gelatinlead oxide mixture was carotid arterially injected and 24 hours of cryopreservation of the body. Three parallel lines with equal interval perpendicular to long axis of the two vessels were designed at the communication area. Vessel anastomosis quantifying was determined by counting the number of marks derived from the intersections of the lines and the vessels and statistical analysis was carried out. Results The mark of intersectionin expanded group (81.20±10.33) was more than that in unexpanded group (22.40±5.41), showing significant difference(Plt;0.01). Conclusion The method for quantifying vessel anastomosis in skin flap is simple, reliable, and easytoperform. The principles of this procedure may also be applied to other experimental and clinical studies.
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.
