ObjectiveTo evaluate the methods and effectiveness of contralateral C7 nerve root and multiple nerves transfer for the treatment of brachial plexus root avulsion. MethodsBetween June 2006 and June 2010, 23 patients with brachial plexus root avulsion were treated. There were 20 males and 3 females, aged 17 to 42 years (mean, 27.4 years). The time from injury to operation was 4 to 12 months (mean, 5.9 months). In 16 patients having no associated injury, the first stage procedure of contralateral C7 nerve root transfer and accessory nerve transfer to suprascapular nerve or phrenic nerve transfer to anterior upper trunk was performed, and the second stage procedure of the contralateral C7 nerve root transfer to median nerve and intercostal nerve transfer to axillary nerve was performed. In 4 patients having phrenic nerve and accessory nerve injuries, the first stage procedure of the contralateral C7 nerve root transfer and second stage procedure of the contralateral C7 nerve root transfer to median nerve and musculocutaneous nerve were performed. In 3 patients having hemothorax, pneumothorax, and rib fractures, the first stage procedure of the contralateral C7 nerve root transfer and accessory nerve transfer to suprascapular nerve, and the second stage procedure of the contralateral C7 nerve root transfer to median nerve and musculocutaneous nerve were performed. The British Medical Research Council (MRC) sensory grading (S0-S4) and modified muscle strength grading standard (M0-M5) were used for comprehensive assessment of limb and shoulder abduction, elbow/biceps muscle strength, flexor wrist and finger muscle strength and median nerve sensory recovery. ResultsTwenty-three patients were followed up 3-4.5 years (mean, 3.4 years). At 3 years after operation, the shoulder abduction reached 0-82°(mean, 44°). In 16 patients having no associated injuries, the shoulder abduction was more than 30°in 13 cases, and was more than 60°in 3 cases; in 3 patients having hemothorax, pneumothorax, and rib fractures, the shoulder abduction was more than 30°; and in 4 patients having phrenic nerve and accessory nerve injuries, the shoulder abduction was 0°. The muscle strength of elbow/biceps was M3 or more than M3 in 9 cases, was M1-M2 in 8 cases, and was M0 in 6 cases; the muscle strength of flexor wrist or finger was M3 or more than M3 in 7 cases, was M1-M2 in 11 cases, and was M0 in 5 cases. Median nerve sensory recovery was S3 or more than S3 in 11 cases, was S1-S2 in 7 cases, and was S0 in 5 cases. After 3 years, affected limb had locomotor activity in 11 patients, affected limb had activities driven by the contralateral latissimus dorsi muscle contraction in 12 patients. ConclusionContralateral C7 nerve root and multiple nerves transfer is a good method to treat brachial plexus root avulsion.
ObjectiveTo study the digital anatomy and application value of the thoracic dorsal artery based on CT angiography (CTA). MethodsBetween September 2012 and June 2014, aorta CTA images were chosen from 10 cases (20 sides) undergoing aorta CTA. By using Mimics 17.0 software for three dimensional (3D) reconstruction of image post-processing, the digital vascular anatomical information were obtained after observing and measuring the origin of the thoracic dorsal artery, the number of perforators, type, inner diameter, and pedicle length; and the body surface location of perforator vessel was determined, and then the thoracic dorsal artery perforators tissue flap harvesting was simulated. Results3D reconstruction images showed that the thoracic dorsal artery originated from subscapular artery, 76 perforator vessels were found, including 32 perforators (42.1%) from the medial branch of the thoracic dorsal artery and 44 perforators (57.9%) from the lateral branch of the thoracic dorsal artery, of which 69 were intramuscular perforators (90.8%) and 7 were direct skin artery (9.2%). The inner diameter of the thoracic dorsal artery was (1.69±0.23) mm, and its pedicle length was (2.12±0.64) cm. The first lateral perforator of the thoracic dorsal artery located at (1.65±0.42) cm above the horizontal line of the inferior angle of scapula and at (1.68±0.31) cm lateral to vertical line of the inferior angle of scapula. The first medial perforator located at (1.43 ±0.28) cm above the horizontal line of the inferior angle of scapula and at (1.41±0.28) cm lateral to vertical line of the inferior angle of scapula. The thoracic dorsal artery perforators flap harvesting was successfully simulated. ConclusionCTA is a more intuitive method to study the thoracic dorsal artery in vivo, it can clearly display 3D information of the main blood supply artery course and distribution after flap reconstruction, so it can effectively and accurately guide the design of the flap.