Direct Repair of the Lower Trunk to Residual Nerve Roots for Restoration of Finger Flexion After Total Brachial Plexus Injury.

PURPOSE: Residual nerve root stumps have been used to neurotize the median nerve in an attempt to restore finger flexion function in patients suffering from total brachial plexus injury. However, the results have been unsatisfactory mainly because of the need to use a long nerve graft. The authors have tried to improve the quality of restored finger flexion by direct approximation of available (ruptured) ipsilateral root stumps to the lower trunk (LT). We sought to validate these results using objective outcome measures. METHODS: This is a study of 27 cases of total posttraumatic brachial plexus palsies. In each case, the neck was explored and ruptured root stumps identified. The LT was mobilized by separating it from the posterior division and the medial cutaneous nerve of the forearm distally. The mobilized LT was then approximated directly to an ipsilateral root stump. The arm was immobilized against the trunk for 2 months. The patients were observed for return of function in the paralyzed upper limb. The presence and strength of finger flexion was measured using the British Medical Council grading. RESULTS: The follow-up period was 36 to 74 months (average, 56.9 ± 13.7 months). Recovery of active finger flexion was M4 in 10 patients, M3 in 8 patients, and M2 to M0 in 9 patients. Meaningful recovery (M3 or greater) of finger flexion was achieved in 18 of 27 patients. CONCLUSIONS: The results of active finger flexion can be improved by direct approximation of the LT to an ipsilateral root stump. TYPE OF STUDY/LEVEL OF EVIDENCE: Therapeutic IV.

Restoration of active pick-up function in patients with total brachial plexus avulsion injuries.

We designed multiple nerve transfers in one surgery to restore active pick-up function in patients with total brachial plexus avulsion injuries. Forty patients with total brachial plexus avulsion injuries first underwent multiple nerve transfers. These included transfer of the accessory nerve onto the suprascapular nerve to recover shoulder abduction, contralateral C7 nerve onto the lower trunk via the modified prespinal route with direct coaptation to restore lower trunk function and onto the musculocutaneous nerve with interpositional bridging by medial antebrachial cutaneous nerve arising from lower trunk to restore elbow flexion, and the phrenic nerve onto the posterior division of lower trunk to recover elbow and finger extension. At least three years after surgery, the patients who had a meaningful recovery were selected to perform secondary reconstruction to restore active pick-up function. Active pick-up function was successfully restored in ten patients after they underwent multiple nerve transfers combined with additional secondary functional hand reconstructions. LEVEL OF EVIDENCE: IV.

Direct Coaptation of the Phrenic Nerve With the Posterior Division of the Lower Trunk to Restore Finger and Elbow Extension Function in Patients With Total Brachial Plexus Injuries.

BACKGROUND: To overcome the mismatch in nerve sizes in phrenic nerve transfer to the radial nerve for elbow and finger extension reanimation for patients with total brachial plexus injuries (TBPI), a selective neurotization procedure was designed. OBJECTIVE: To investigate the long-term results of phrenic nerve transfer to the posterior division of the lower trunk with direct coaptation in restoring elbow and finger extension after TBPI. METHODS: Phrenic nerve was transferred to and directly coapted with the posterior division of the lower trunk in 27 patients with TBPI. Seven patients were <18 years old (adolescent group), and the remaining 20 patients ≥18 years (adult group). RESULTS: Postoperative mean follow-up period was 54 ± 9 months (range, 48-85 months). The motor function attained M3 or greater in 81.5% of patients for elbow extension and in 48% of patients for finger extension. The percentage of patients who regained M3 or greater muscle power of finger extension in the adolescent group and the adult group was 71.4%, and 40%, respectively. Meanwhile, 85.7% in the adolescent group and 80% in the adult group achieved M3 or greater muscle power of elbow extension. There were no significant differences between the 2 groups. The elbow extension and finger extension were synchronous contractions and did not become independent of respiratory effort. CONCLUSION: This procedure simultaneously and effectively restores the function of elbow and finger extension in patients after TBPI. However, the patients could not do elbow and finger extension separately.

Contralateral C7 Nerve Transfer with Direct Coaptation to Restore Lower Trunk Function After Traumatic Brachial Plexus Avulsion Injuries: Surgical Technique.

INTRODUCTION: We describe a new technique for treating traumatic brachial plexus avulsion injury with a contralateral C7 nerve transfer with direct coaptation that shortens the time to muscle reinnervation. STEP 1 EXPLORE THE INJURED BRACHIAL PLEXUS: Explore the brachial plexus carefully and confirm the nerve-root avulsion injuries from C7 to T1. STEP 2 HARVEST THE CONTRALATERAL C7 NERVE: Dissect the divisions of the contralateral C7 nerve root, divide the nerve at the junction between the divisions and cords, and mobilize it proximally. STEP 3 CREATE THE PRESPINAL ROUTE: Create the prespinal route to guide the contralateral C7 nerve to the injured side. STEP 4 HUMERAL SHORTENING OSTEOTOMY: If the contralateral C7 nerve does not reach the injured lower trunk, perform a humeral shortening osteotomy, generally with <5 cm of shortening in adults. STEP 5 NEURORRHAPHY: Suture one end of the sural nerve together with the medial antebrachial cutaneous nerve to the musculocutaneous nerve; anastomose the remainder of the contralateral C7 nerve directly with the lower trunk. STEP 6 POSTOPERATIVE CARE: Use a prefabricated brace to hold the head in the neutral position and immobilize the injured limb for six weeks. RESULTS: We evaluated the results of the technique in a study of seventy men and five women with a mean age (and standard deviation) of 28 ± 10 years (range, ten to fifty-three years).IndicationsContraindicationsPitfalls & Challenges.

Contralateral C7 nerve transfer with direct coaptation to restore lower trunk function after traumatic brachial plexus avulsion.

BACKGROUND: Contralateral C7 nerve transfer to the median nerve has been used in an attempt to restore finger flexion in patients with total brachial plexus avulsion injury. However, the results have not been satisfactory mainly because of the requirement to use a long bridging nerve graft, which causes an extended nerve regeneration process and irreversible muscle atrophy. A new procedure involving contralateral C7 nerve transfer via a modified prespinal route and direct coaptation with the injured lower trunk is presented here. METHODS: Contralateral C7 nerve transfer via the modified prespinal route and direct coaptation with the injured lower trunk was performed in seventy-five patients with total brachial plexus avulsion injury. Thirty-five required humeral shortening osteotomy (3 to 4.5 cm) in order to accomplish the direct coaptation. The contralateral C7 nerve was also transferred to the musculocutaneous nerve through the bridging medial antebrachial cutaneous nerve arising from the lower trunk in forty-seven of the seventy-five patients. Recovery of finger, wrist, and elbow flexion was evaluated with use of the modified British Medical Research Council muscle grading system. RESULTS: The mean follow-up period (and standard deviation) was 57 ± 6 months (range, forty-eight to seventy-eight months). Motor function with a grade of M3+ or greater was attained in 60% of the patients for elbow flexion, 64% of the patients for finger flexion, 53% of the patients for thumb flexion, and 72% of the patients for wrist flexion. CONCLUSIONS: Contralateral C7 nerve transfer via a modified prespinal route and direct coaptation with the injured lower trunk decreases the distance for nerve regeneration in patients with total brachial plexus avulsion injury. There was satisfactory recovery of finger flexion and wrist flexion in this series. In addition, contralateral C7 nerve transfer was successfully used to repair two different target nerves: the lower trunk and the musculocutaneous nerve.

Electrophysiological study of the dominant motor innervation to the extensor digitorum communis muscle and long head of triceps brachii at posterior divisions of brachial plexus.

BACKGROUND: Restoration of elbow and finger extension function is still challenging in management of complete brachial plexus avulsion injury, mainly because of fewer available donor nerves for transfer to the radial nerve. Selective neurotization could be a potentially alternative for overcoming this dilemma. This study was designed to identify the innervation dominance of the extensor digitorum communis muscle (EDCM) and long head of the triceps brachii (LTB) at the level of division of brachial plexus. METHODS: From February 2008 to October 2009, 17 patients with complete brachial plexus avulsion injury underwent the procedure of contralateral C7 nerve root transfer. The posterior divisions of brachial plexus on the healthy donor side were intraoperatively stimulated and the compound muscle action potentials (CMAPs) from the extensor digitorum communis muscle and long head of triceps brachii were recorded by an electrophysiological device. RESULTS: In 13 out of 17 patients (76.5%), the maximal amplitude of CMAP from EDCM was induced by stimulation of the posterior division of lower trunk (PDLT). The mean amplitudes of CMAP from EDCM with stimulation of the posterior division of upper trunk (PDUT), middle trunk (PDMT), and PDLT were 0.64 ± 0.95, 1.64 ± 1.56, and 5.32 ± 4.67 mV (P < 0.05), respectively. The maximal amplitude of CMAP from LTB was induced mainly by stimulation of the PDMT) and PDLT (6 out of 11 and 5 out of 11 patients). The mean amplitudes of CMAP from LTB with stimulation of the PDUT, PDMT, and PDLT were 0.15 ± 0.24, 5.20 ± 4.27, and 7.48 ± 9.90 mV, respectively. The differences of CMAPs between stimulation of PDUT and other two divisions were significant (P < 0.05). CONCLUSIONS: From the electrophysiological point of view, this study showed that the PDLT was the major motor division innervating EDCM, and the PDMT and PDLT shared the similar proportion of LTB innervation.

[The clinical study of reconstruction of traumatic brachial plexus root avulsion injury in children].

OBJECTIVE: To observe the primary result of finger flexion reconstruction in the procedure of direct anastomosis of contralateral C(7) transferred through the prespinal route with lower trunk in children suffered traumatic brachial plexus root avulsion injury. METHODS: On the healthy side, the C(7) nerve root was identified anatomically and transected at the level of division by dissecting its anterior and posterior division as far distal as possible up to the level where the nerve fibers interweaving with other division, then the contralateral C(7) nerve root was dissected proximally up to the neuroforamina. The contralateral C(7) nerve root was transferred to contralateral side through the prespinal route. The entire brachial plexus of suffered side was exposed through the union incision superior and inferior to the clavicle, The lower trunk was identified and dissected proximally to the C(8) and T(1) nerve root which were severed at the lateral margin of anterior scalenus, and then the dorsal division and anterior medial pectoral nerve of lower trunk were severed. The median nerve, ulnar nerve and medial antebrachial cutaneous nerve were identified from the origin and dissected distally continue to the midpoint of upper arm, and lateral head of the median nerve was severed so that the lower trunk, medial cord and median nerve, ulnar nerve and medial antebrachial cutaneous nerve can be fully mobilized. Anteriorly flexion and adduction of the should at 0 degrees and flexion elbow at 90 degrees , this could allow considerable length to be gained when pulling the lower trunk proximally, direct anastomosis of contralateral C(7) with lower trunk was performed. If there was any tension exist, the appropriate humerus shorten osteotomy should be performed. From August 2004 to December 2008, 20 children including 13 cases with total brachial plexus nerve root avulsion injury and 7 cases with middle and lower trunk avulsion injury were repaired by this procedure. Twenty cases including 16 males and 4 females, the average age was 13 years with a range of 5 to 18 years. The interval from injury to operation ranged 1 to 11 months with a mean of 4.6 months. Eleven patients were performed the humeral shorten osteotomy, the length of the humeral shorten was 2.0 - 4.5 cm, with the mean of (3.1 +/- 0.7) cm. RESULTS: The follow up period was 12 to 51 months, with the average of 26 months. The muscle strength of finger flexion attained M 4 in 18 cases, M 2 in 2 cases. The motor function of thumb flexion gained M 4 in 10 cases, M 3 in 8 cases, M2 in 2 cases. Of the 2 cases achieved motor function of intrinsic muscles of the hand of M3. CONCLUSIONS: The direct anastomosis of contralateral C(7) with lower trunk in children with traumatic brachial plexus avulsion injury can improve the effect of reconstructing the function of finger flexion because it reduces one never anastomosis site and decreases the distance of nerve regeneration compared with the traditional method. With this modified procedure, the functional recovery of intrinsic muscles of the hand in children with traumatic brachial plexus avulsion injury is becoming possible.

Management of intra-articular fracture of the fingers via mini external fixator combined with limited internal fixation.

BACKGROUND: Intra-articular fractures of the fingers are common problems to emergency physicians and hand surgeons. Inappropriate management of these injuries may result in chronic pain, stiffness, deformity, or post traumatic arthritis. Ideal treatment necessitates the restoration of a stable and congruent joint that will allow early mobilization. The purpose of this study was to investigate the results of intra-articular fracture of the fingers by mini external fixator combined with limited internal fixation. METHODS: From May 2005 to May 2007, a total of 26 patients with intra-articular fracture of the fingers were treated by mini external fixator combined with limited internal fixation. Of the 26 cases, 11 involved in metacarpophalangeal joint, and 15 interphalangeal joint in proximal interphalangeal. Kirschner wire, mini wire and absorbable suture were used for limited internal fixation. All patients were followed up and patients were accomplished with total active motion (TAM) of fingers. RESULTS: All patients were reviewed by an independent observer. The mean follow up was 13 months (range 9 to 24 months). Subjective, objective and radiographic results were evaluated. X-ray films revealed fracture union and the average radiographic union time was 7 weeks with a range of 5 - 12 weeks and the phalange shortening or rotation in 2 cases, joint incongruity (less than 1 mm) and joint space narrowing in 3 cases respectively. Phalangeal shortening or rotation was observed in 2 cases and joint incongruity or joint space narrowing was observed in 3 cases. An artificial implant was performed on one case for traumatic arthritis 1.5 years after surgery. Based on TAM the overall good-excellent rate of joint motion function was 80.8%. CONCLUSION: Mini external fixator combined with limited internal fixation is a reliable and effective method for treatment of intra-articular fracture of the fingers.