Objective To provide the anatomical basis of contralateral C7 root transfer for the recovery of the forearm flexor function. Methods Thirty sides of adult anti-corrosion specimens were used to measure the length from the end of nerves dominating forearm flexor to the anastomotic stoma of contralateral C7 nerve when contralateral C7 nerve transfer was used for repair of brachial plexus lower trunk and medial cord injuries. The muscle and nerve branches were observed. The length of C7 nerve, C7 anterior division, and C7 posterior division was measured. Results The length of C7 nerve, anterior division, and posterior division was (58.8 ± 4.2), (15.4 ± 6.7), and (8.8 ± 4.4) mm, respectively. The lengths from the anastomotic stoma to the points entering muscle were as follow: (369.4 ± 47.3) mm to palmaris longus, (390.5 ± 38.8) mm (median nerve dominate) and (413.6 ± 47.4) mm (anterior interosseous nerve dominate) to the flexor digitorum superficialis, (346.2 ± 22.3) mm (median nerve dominate) and (408.2 ± 23.9) mm (anterior interosseous nerve dominate) to the flexor digitorum profundus of the index and the middle fingers, (344.2 ± 27.2) mm to the flexor digitorum profundus of the little and the ring fingers, (392.5 ± 29.2) mm (median nerve dominate) and (420.5 ± 37.1) mm (anterior interosseous nerve dominate) to the flexor pollicis longus, and (548.7 ± 30.0) mm to the starting point of the deep branch of ulnar nerve. The branches of the anterior interosseous nerve reached to the flexor hallucis longus, the deep flexor of the index and the middle fingers and the pronator quadratus muscle, but its branches reached to the flexor digitorum superficials in 5 specimens (16.7%). The branches of the median nerve reached to the palmaris longus and the flexor digitorum superficial, but its branches reached to the deep flexor of the index and the middle fingers in 10 specimens (33.3%) and to flexor hallucis longus in 6 specimens (20.0%). Conclusion If sural nerve graft is used, the function of the forearm muscles will can not be restored; shortening of humerus and one nerve anastomosis are good for forearm flexor to recover function in clinical.
ObjectiveTo provide the anatomical basis for the selection of osteotomy site in leg lengthening or tibial slip. MethodsBetween August 2010 and July 2014, 10 adult fresh amputated leg specimens were collected. The pressure perfusion of red latex was performed by the popliteal artery. The anterior tibial artery and its main branches were separated and exposed, and the periosteal branch of anterior tibial artery was adequately exposed;the posterior tibial artery and its main branches were exposed;the peroneal artery was separated and exposed. The tibial and peroneal artery and its branches were observed and measured. When measuring the proximal end, the medial tibial plateau bone margin, the most prominent part of the tibial tuberosity, and the fibular head edge were used as a reference;when measuring the distal end, distal medial condyle of tibia malleolus tip, tibial lateral malleolus lateral tip, and distal tibial articular surface were used as a reference;the vertical distance between tibia proximal and distal main arteries and bone end reference was measured to determine the optimal osteotomy position of upper and lower tibia. The osteotomy index was calculated which was used to represent the relative position of osteotomy site in the whole tibia. ResultsThe proximal tibial osteotomy site located at (78.2±19.5) mm from medial tibial plateau margin, (41.8±16.0) mm from the tibial tuberosity pole, and (66.7±16.4) mm from the fibular head edge. The distal tibial osteotomy site located at (70.8±12.1) mm above the inferior margin of tibial medial malleolus, (83.3±13.0) mm above the inferior margin of lateral malleolus tip, and (59.1±11.7) mm from distal tibial articular surface. The proximal tibial osteotomy index was 18.45-23.35 (mean, 20.46);the distal tibial osteotomy index was 14.36-23.05 (mean, 18.81). ConclusionThe metaphyseal-diaphyseal connection shold be selected in the proximal and distal tibia osteotomy, the lower one third of the tibia is not suitable for ostetomy.
ObjectiveTo discuss the effectiveness of femoral-femoral artery bypass grafting combined with transverse tibial bone transporting in treatment of lower extremity arteriosclerosis obliterans (ASO) or combined with diabetic foot. MethodsBetween March 2014 and June 2016, 9 patients with lower extremity ASO or combined with diabetic feet were treated with femoral-femoral artery bypass grafting and transverse tibial bone transporting. All patients were male, aged from 63 to 82 years with an average of 74.2 years. The disease duration of ASO was 1.5-22.0 months (mean, 10.5 months). All cases were severe unilateral iliac arterial occlusion, including 5 cases of the left side and 4 cases of the right side. There were 7 cases with superficial femoral and/or infrapopliteal artery disease. There were 7 cases of ASO and 2 cases of ASO combined with diabetic foot (Wagner grade 4); all the ASO were grade Ⅳ according to Fontaine criteria. All patients had rest pain before operation, and the ankle brachial index was 0.24±0.12. In femoral-femoral artery bypass grafting operations, artificial blood vessels were used in 7 cases and autologous saphenous vein were used in the other 2 cases. The tibial bone transverse transporting began on the 8th day after operation by 1 mm per day and once per 6 hours; after transported for 2-3 weeks, it was moved back. The whole course of treatment was 10-14 weeks. ResultsThe incision of tibial bone transverse transporting was necrotic in 1 case, and healed after dressing change. There was no obvious complication at the orifice of the needle. The other patients had no incision complication. The granulation tissue of foot wound was growing quickly after tibial bone transverse transporting, and the wound was reduced after 2-3 weeks. All the 9 patients were followed up 12-32 months (mean, 19 months). The ankle brachial index was 0.67±0.09 at 2 months postoperatively, which was significantly higher than that before operation (t=17.510, P=0.032). All the feet ulcer wounds healed and the healing time was 6.7-9.4 weeks (mean, 7.7 weeks). During follow-up, color Doppler ultrasound or CT examination revealed grafted blood vessel patency. The external fixator was removed at 12-14 weeks after operation. One case died of sudden myocardial infarction at 14 months after operation, and there was no lymphatic leakage. The patency rate of femoral-femoral bypass was 100% at 1 year after operation. The tibial transverse bone grafting healed with tibia at 4-6 months after operation. At last follow-up, the effective rate was 100%. ConclusionFemoral-femoral artery bypass grafting combined with transverse tibial bone transporting is an effective method in the treatment of lower extremity ASO or combined with diabetic foot.