OBJECTIVE
The authors sought to describe the anatomy of the radial nerve and its branches when exposed through an axillary anterior arm approach.
METHODS
Bilateral upper limbs of 10 fresh cadavers were dissected after dyed latex was injected into the axillary artery.
RESULTS
Via the anterior arm approach, all triceps muscle heads could be dissected and individualized. The radial nerve overlaid the latissimus dorsi tendon, bounded by the axillar artery on its superior surface, then passed around the humerus, together with the lower lateral arm and posterior antebrachial cutaneous nerve, between the lateral and medial heads of the triceps. No triceps motor branch accompanied the radial nerve’s trajectory. Over the latissimus dorsi tendon, an antero-inferior bundle, containing all radial nerve branches to the triceps, was consistently observed. In the majority of the dissections, a single branch to the long head and dual innervations for the lateral and medial heads were observed. The triceps long and proximal lateral head branches entered the triceps muscle close to the latissimus dorsi tendon. The second branch to the lateral head stemmed from the triceps lower head motor branch. The triceps medial head was innervated by the upper medial head motor branch, which followed the ulnar nerve to enter the medial head on its anterior surface. The distal branch to the triceps medial head also originated near the distal border of the latissimus dorsi tendon. After a short trajectory, a branch went out that penetrated the medial head on its posterior surface. The triceps lower medial head motor branch ended in the anconeus muscle, after traveling inside the triceps medial head. The lower lateral arm and posterior antebrachial cutaneous nerve followed the radial nerve within the torsion canal. The lower lateral brachial cutaneous nerve innervated the skin over the biceps, while the posterior antebrachial cutaneous nerve innervated the skin over the lateral epicondyle and posterior surface of the forearm. The average numbers of myelinated fibers were 926 in the long and 439 in the upper lateral head and 658 in the upper and 1137 in the lower medial head motor branches.
CONCLUSIONS
The new understanding of radial nerve anatomy delineated in this study should aid surgeons during reconstructive surgery to treat upper-limb paralysis.
This article is based on literature review of relevant articles as well as the authors’ own experiences in treating peripheral nerve injuries of the lower limb. The article deals with causative factors of lower limb nerve injuries, various grading systems of the injuries, approaches to such injuries, and techniques to repair lower limb nerve injuries. It also enumerates several reasons to explain the poorer prognosis of peroneal nerve injuries and the possible distal nerve transfers in lower limb albeit with poorer outcomes.
Background Children with birth brachial plexus injury (BBPI) often require secondary surgery for the shoulder. The shoulder spica is necessary after shoulder muscle transfer surgery in babies with BBPI. However, its application can be difficult in the supine position under anesthesia. The authors describe a simple and cost-effective method of applying the shoulder spica cast without changing the supine position under anesthesia.
Technique While still under anesthesia, the child is placed in a supine position and then elevated on the wooden bar. The POP roll is wrapped around in a cylindrical manner, starting from the level one inch above the anterior superior iliac spine. The contralateral shoulder is also incorporated into the cast.
Conclusion The spica application technique described comprises commonly available materials, such as a wooden plank, pair of bolsters, plaster of Paris rolls, and dressing materials overcoming the need for customized apparatus or the operation table. The materials are easy to assemble and thereby applicable just about anywhere. The task also becomes less challenging for the anesthetic in the supine position. This technique is easily reproducible and cost-effective.
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