Objective To investigate the quantity and distribution of motor fiber of rat’s C7 nerve root. Methods Motor fiber quantity and section area in the main nerves of the upper extremity and the fascicles of C7 in 30 SD rats were analyzed.Results Fascicles and certain amount (207) of motor fibers from the anterior division of C7 were distributed to musculocutaneous nerve and median nerve, the orientation of these fibers were not clear. The ones (323) from posterior division were to the axillary, radial, and dorsal thoracic nerves, thus the orientation of these fascicles was relatively definite. Conclusion Thedistribution of the motor fibers and fascicles in the divisions of C7 in rat is similar to human beings, so rat is a relatively good model for the study of selective C7 nerve root transfer.
OBJECTIVE: To investigate the variation of neurotrophic factors expression in spinal cord and muscle after root avulsion of brachial plexus. METHODS: Forty-eight Wistar rats were involved in this study and according to the observing time in 1st day, 1st week, 4th week, 8th week, and 12th week after avulsion, and the control, were divided into 6 groups. By immunohistochemical and hybridization in situ assays, the expression of nerve growth factor (NGF) on muscle, basic fibroblast growth factor(bFGF) and its mRNA on the neurons of corresponding spinal cord was detected. Computer image analysis system was used to calculate the result. RESULTS: After the root avulsion of brachial plexus occurred, expression of NGF increased and reached to the peak at the 1st day. It subsided subsequently but was still higher than normal control until the 12th week. While expression of bFGF and its mRNA increased in the neurons of spinal cord and reached to the peak at the 1st week. Then it dropped down and at the 12th week it turned lower than normal control. CONCLUSION: After root avulsion of brachial plexus, neurotrophic factors expression increase on target muscle and neurons of corresponding spinal cord. It maybe the autoregulation and may protect neuron and improve nerve regeneration.
Objective To observe the recovery of the sensory and motor function of the repaired l imb and the impact on the healthy l imb function after contralateral C7 nerve root transposition for treating brachial plexus root avulsion injury. Methods Between August 2008 and November 2010, 22 patients with brachial plexus root avulsion injuries were treated with contralateral C7 nerve root transposition. All patients were male, aged 14 to 47 years (mean, 33.3 years). Total brachialplexus root avulsion was confirmed by preoperative cl inical examination and electrophysiological tests. In 22 cases, median nerve was repaired in 16 cases, radial nerve in 3 cases, and musculocutaneous nerve in 3 cases; primary operation was performed in 2 patients, and two-stage operation was performed in 20 patients. The sensory and motor functional recovery of the repaired limb was observed after operation. Results Twenty-one patients were followed up 7-25 months (mean, 18.4 months). In 16 cases of contralateral C7 nerve root transposition to the median nerve, wrist flexors reached more than M3 in 10 cases, while finger flexors reached more than M3 in 7 cases; sensation reached more than S3 in 11 cases. In 3 cases of contralateral C7 nerve root transposition to the musculocutaneous nerve, elbow flexors reached more than M3 in 2 cases; sensation reached more than S3 in 2 cases. In 3 cases of contralateral C7 nerve root transposition to the radial nerve, wrist extensor reached more than M3 in 1 case; sensation reached more than S3 in 1 case. Conclusion Contralateral C7 nerve root transposition is a good procedure for the treatment of brachial plexus root avulsion injury. Staged operation is one of important factors influencing treatment outcome.
ObjectiveTo investigate the management strategies of clavicular fracture combined with brachial plexus injury and its effectiveness. MethodsBetween January 2006 and January 2012, 27 cases of clavicular fracture combined with brachial plexus injury were treated. There were 18 males and 9 females, aged 18-42 years (mean, 25.3 years). The causes of injury were traffic accident in 12 cases, falling from height in 10 cases, bruise in 3 cases, machinery injury in 2 cases. According to the Robinson classification, the clavicular fractures were rated as type Ⅰ in 2 cases, as typeⅡin 20 cases, and as type Ⅲ in 5 cases; there were 12 cases of total brachial plexus root avulsion injury, 10 cases of bundle branch injury, and 5 cases of hematoma formation and local nerve compression or injury. The injury to operation time was 6 hours to 14 days (mean, 4 days). Brachial plexus injury was repaired by epineurium neurolysis, nerve anastomosis, or nerve transposition after the exploration of the plexus; and fracture was fixed after open reduction. Sensory grading standard (S0-S4) by UK Medical Research Council (MRC) was used to evaluate the recovery of sensory function, and muscle strength grading standard (M0-M5) by MRC to evaluate the innervating muscle strength. ResultsThe incisions healed by first intention. All patients were followed up 18-36 months (mean, 26.3 months). All fracture achieved cl inical healing at 12-17 weeks (mean, 15 weeks). No complication of loosening or breakage of internal fixation occurred. The patients had no pain of shoulder in abduction. At 18 months after operation, the shoulder abduction was more than or equal to 60° in 8 cases, 30-60° in 8 cases, and less than 30° in 11 cases. The recovery of biceps muscle strength was more than or equal to M3 in 18 cases and less than M3 in 9 cases; the recovery of wrist flexion or flexor muscle strength was more than or equal to M3 in 13 cases and less than M3 in 14 cases. The sensory function recovery of median nerve was S3 in 14 cases, S1-S2 in 9 cases, and S0 in 4 cases. The shoulder abduction, elbow and wrist flexor motor function did not recover in 2 patients with total brachial plexus root avulsion injury. ConclusionIt is beneficial to the recovery of nerve function to early repair of the brachial plexus injury by exploration of the plexus combined with open reduction and fixation of clavicular fractures, the short-term effectiveness is good.
Objective To investigate the sensation of the fingers innervated by the brachial plexus roots and provide the theoretic basis for diagnosis of a brachial plexus injury. Methods From June 2003 to January 2005,10 patients (8 males, 2 females; age,18-47 years) with complete brachial plexus avulsion were involved in this study, who underwent thecontralateral C7 nerve root transfer. The latency and amplitude of the sensory nerve actiopotential(SNAP) were record at the C5 T1 nerve roots when stimulation was given at the fingers.Results When the thumb and the index finger were stimulated and SNAP was recorded at all the roots of the brachial plexus in all the patients, we found that there was a higher amplitude and a shorter latency at the C5-7 roots than at the C8 and T1 roots(P<0.05). When the middle finger was stimulated and SNAP was recorded at the C7,8 and T1 roots, we found that there was the highest amplitude and the shortest laency at the C7 root(P<0.01). When the ring finger was stimulated and SNAP was recorded at the C7,8and T1 roots, we found that there was a higher amplitude and a shorter latency at the C8 and T1 roots than at the C7 root(P<0.01). When the little finger was stimulated and SNAP was recorded at the C7,8and T1 roots, we found that there was the highest amplitude and the shortest latency at the T1 root(P<0.01). ConclusionThe sense of the thumband the index finger is mainly nnervated by the C5-7 roots, the middle finger sense is mainly innervated by the C7 root, the ring finger sense is mainly innervated by the C8 and T1 roots, and the little finger sense is mainly innervated by the T1 root.
Objective To explore the effect of spinal neural progenitor transplantation to the cervical spinal on treating brachial plexus injury with the reimplantation of the avulsed spinal roots. Methods Thebrachial plexusavulsed injury model was made on 54 rats and they were evenly divided into 3 groups: fresh group, chronic group, control group. The spinal neural progenitor was cultured and identified. Then 10 μl(1×105/μl)cells were labelled with BrdUand transplanted into the fresh group (15 rats survived, being model for 1 week) and the chronic group (14 rats survived, being model for 2 months). No cell was transplanted into the control group. Two months after the transplantation, therecovery of function of the injured limb was evaluated. Electrophysiologic study and immunohistochemical study of the injured limb were made. Results Spinal neural progenitors were isolated from the spine and became neural sphere. The neural spheres were differentiated into neurons and astrocytes. Fourteen rats out of 15 in the fresh group were recovered, 7 rats out of 14 in the chronic groupwere recovered, and 5 rats out of 12 in the control group were recovered. Immunohistochemical study indicated that the transplanted progenitors in fresh group survived and differentiated into the neural cells, and the transplanted progenitors in chronic group existed and did not differentiate well. Conclusion Transplanted spinal neural progenitors can promote the recovery of the brachial plexus injury with the reimplantation of the avulsed spinal root.
OBJECTIVE To explore the regularity of the change of S-100 protein in degenerative nerve after different pathological brachial plexus injuries. METHODS Eighty SD rats were randomly divided into two groups, right C5, C6 preganglionic injury, and postganglionic injury. The distribution and content of S-100 protein in distal degenerative nerve were detected after 1, 2, 3 and 6 months of injury by immunohistochemical methods. RESULTS The S-100 protein was mainly distributed along the axons. The S-100 protein positive axons of each time interval decreased after operation, with significant difference from normal nerves (P lt; 0.01). There was no statistically significant difference among 1, 2, 3 and 6 months group (P gt; 0.05). The S-100 protein stain of postganglionic group was negative. CONCLUSION In preganglionic injury, the functional expression of Schwann’s cells in the distal stump keeps at a certain level and for a certain period. Since Schwann’s cell has inductive effect on nerve regeneration, it suggests that the distal nerve stump in preganglionic injury can be used as nerve grafts.
Objective〓〖WTBZ〗To assess treating results of functional reconstruction of irrecoverable partial injury of brachial plexus and to improve the function ofinjured upper extremity. Methods Seventiy-nine cases with irrecoverable partial injury of brachial plexus were treated in transfer of muscle (tendon) or by fuctional anthrodesis (fixation of tendon) from January 1984 to June 2003. According to the evaluation criterion by American Shoulder and Elbow, Hand Association,all patients were followed up in motion of reconstructive joint and daily activities after operation for 1 year to 19 years. The effect of the operation was comprehensively scored and evaluated. Results Final results in 54 caseswere as follows: 30 patients with good results, 19 patients with fair results, and 5 with poor results. The results demonstrated some points as follow: ①if the shoulder was instable, athroedesis of shoulder would be a better choice;②the flexion of the elbow joint should be only reconstructed with the dynamic reconstructive methods. The reconstruction of flexion of elbow by transfer of pectoral major muscle was more effective than that by transfer of flexor carpi ulnaris muscle; ③the dynamic reconstruction of extension of digital and carpi was better than that of flexion of digital and opposition function of the thumb; ④the supination of the forearm was effectively reconstructed by transfer of flexorcarpi ulnaris muscle. Pronation teres muscle should be studied more in reconstruction of supination function of the forearm.
Objective To analysis the electrophysiological dominance weight of the triceps brachii muscle/extensordigitorum communis muscle innervated by brachial plexus and to conclude its effect on the ipsilateral C7 transfer so as to offer electrophysiological data for the safety and indication of i psilateral C7 transfer. Methods From August 2007 to October 2007, 15 patients with complete brachial plexus nerve root avulsion received contralateral C7 transfer. There were 13 males and 2 females aged 18-49 years (28 years on average). Injury was caused by fall ing in 1 case, by crush in 2 cases and by traffic accident in 12 cases, involving left side in 8 cases and right side in 7 cases. The upper, middle and lower trunk of the brachial plexus were stimulated respectively, the compound muscle action potential (CMAP) at the triceps brachii muscle/extensor digitorum communis muscle was recorded, and then the electrophysiological dominance weight of the triceps brachii muscle/extensor digitorum communis muscle innervated by brachial plexus was confirmed according to the comparison of the ampl itude percentage of the CMAP by three trunks. The muscle strength of triceps brachii muscle/extensor digitorum communis muscle was evaluated and the electromyogram was taken 6 months after operation. Results All patients were followed up for 6 months. Concerning the electrophysiological dominance weight, the triceps brachii muscle was mainly innervated by uppermiddle trunk in 3 cases (20%), by middle-lower trunk in 3 cases (20%), by whole trunk in 7 cases (47%) and by middle trunk in 2 cases (13%). While the extensor digitorum communis muscle was mainly innervated by middle-lower trunk in 3 cases (20%), by whole trunk in 10 cases (67%) and by lower trunk in 2 cases (13%). Concerning the triceps brachii muscle, 2 patients got the muscle strength of 4 grade with recruitment simple phase at 1 month after operation and returned to normal at 3 month after operation, while 13 patients got the muscle strength of 5 grade with recruitment simple or mixed phase at 1 month after operation. Concerning the extensor digitorum communis muscle, the muscle strength and the recruitment phase of all 15 patients recovered to normal at 1 month after operation. Conclusion To patients with various kinds of electrophysiological dominance weight, the cutting of C7 does not substantially damage the triceps brachii muscle or extensor digitorum communis muscle, indicating that the ipsilateral C7 transfer is safe and feasible. However, it should be appl ied prudently for the patients with high dominance weight since it may result in the short-term decrease of triceps brachii muscle strength.
Objective To investigate the results of two stage multiple nerves transfer for treatment of complete brachial plexus root avulsion. Methods Eight patients with complete brachial plexus avulsion, aging 18-38 years andwith a mean 6 months interval of injury and repair, were surgically treated with the following procedures. One stage surgical procedure was that the contralateral C7 never root was transferred to the ulnar nerve, the phrenic nerve to theanterior division of upper trunci plexus brachialis and the accessory nerve to the suprascapular nerve. Two stage surgical procedure was that the ulnar nerve was transferredto the median nerve , the intercostal nerves to the radial nerve and the thoracodorsal nerve. Results All patients were followed upfrom 13 months to 25 months(21 months on average), muscle reinnervation was observed in all patients. Return of muscle power of M3 or better are regarded as effective. The effective recovery results were 75% in musculocutaneous nerve, 37.5% in suprascapular nerve, 37.5% in radial nerve, 75% in thoracodorsal nerve and 62.5% in median nerve. In sensory recovery of the median nerve, 4 patients obtained S3, 3 patients S2 and 1 patient S1. Conclusion Two stage multiple nerves transfer for treatment of root avulsion of brachial plexus can achieve better motor function results and is safe and effective. The procedure should be recommended for treatmentof root avulsion of brachial plexus in selected patients with complete brachial plexus root avulsion, especially in young patients with a short interval between injury and repair. It isone of the alternative options.