【Abstract】 Objective To observe the distribution feature of nerve bundles in C7 nerve anterior and posterior division end. Methods The brachial plexus specimen was harvested from 1 fresh adult cadaver. After C7 nerve was confirmed, the distal end of anterior and posterior division was dissected and embedded by OCT. Then the samples were serially horizontally sliced with each 10 μm deep. After acetylcholinesterase (AChE) histochemical staining, the stain characteristics of different nerve fiber bundles were observed and amount of the nerve fiber bundles were counted under optic-microscope. At last, the imaging which were collected were three-dimensional (3-D) reconstructed by using Amira 4.1 software. Results There was no obvious difference in the stain between the anterior and posterior divisions. The running of the nerve fiber bundles were dispersive from proximal end of nerve to distal end of nerve. Nerve fiber bundles of anterior division were mainly sensor nerve fiber bundles, which located in medial side. Nerve fiber bundles of posterior division were mainly moter nerve fiber bundles, having no regularity in the distribution of nerve fiber bundles. The total number of nerve fiber bundles in distal end of anterior division was 7.85 ± 1.04, the number of motor nerve fiber bundles was 2.85 ± 0.36, and the number of sensor nerve fiber bundles was 5.13 ± 1.01. The total number of nerve fiber bundles in distal end of posterior division was 9.79 ± 1.53, the number of motor nerve fiber bundles was 6.00 ± 0.69, and the number of sensor nerve fiber bundles was 3.78 ± 0.94. There were significant differences in the numbers of motor and sensor nerve fiber bundles between anterior and posterior divisions (P lt; 0.05). The microstructure 3-D model was reconstructed based on serial slice through Amira 4.1. The intercross and recombination process of nerves bundles could be observed obviously. The nerve bundle distribution showed cross and combination. Conclusion Nerve fiber bundles of anterior division are mainly sensor nerve fiber bundles and locate in medial side. Nerve fiber bundles of posterior division are mainly motor nerve fiber bundles, which has no regularity in the distribution of nerve fiber bundles. The 3-D reconstruction can display the internal structure feature of the C7 division end.
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.
【Abstract】 Objective To investigate the feasibil ity of contralateral C7 nerve transfer via posterior spinal route fortreatment of brachial plexus root avulsion injury by anatomical study. Methods Ten cadaveric specimens of 7 men and3 women were selected, who had no obvious deformity and no tissue defect in neck neutral position. By simulating surgical exploration of brachial plexus injury, the length of contralateral C7 nerve root was elongated by dissecting its anterior and posterior divisions to the distal end, while the length of C7 nerve from the intervertebral foramen to the branching point and the length of the anterior and posterior divisions were measured. By simulating cervical posterior approach, the C7 vertebral plate and T1 spinous process were fully exposed; the hole was made near vertebral body; and the C7 nerve root lengths by posterior vertebra path to the contralateral upper trunk and lower trunk were measured. Results C7 nerve root length was (58.62 ± 8.70) mm; the length of C7 nerve root plus posterior or anterior division was (65.15 ± 9.11) mm and (70.03 ± 10.79) mm, respectively. By posterior spinal route, the distance was (72.12 ± 10.22) mm from the end of C7 nerve to the contralateral upper trunk of brachial plexus, and was (95.21 ± 12.50) mm to the contralateral lower trunk of brachial plexus. Conclusion Contralateral C7 nerve can be transferred to the contralateral side through posterior spinal route and it only needs short bridge nerve or no. The posterior spinal route can effectively prevent from neurovascular injury, so it might be the best surgery approach for the treatment of brachial plexus root avulsion injury.
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.
Objective To investigate the anatomical evidence of low end-to-side anastomosis of median nerve and ulnar nerve in repair of Dejerine Klumpke type paralysis or high ulnar nerve injury. Methods Twelve formaldehyde anticorrosion specimens (24 sides) and 3 fresh specimens (6 sides) were observed. There were 9 males (18 sides) and 6 females(12 sides). The specimen dissected under the microscope. S-shape incision was made at palmar thenar approaching ulnar side, the profundus nervi ulnaris and superficial branch of ulnar nerve were separated through near end of incision, and the recurrent branch of median nerve and comman digital nerve of the ring finger were separated through far end of incision. The distances from pisiform bone to the start point of the recurrent branch of median nerve, and to the start point of comman digital nerve of the ring finger were measured. The width and thickness of the profundus nervi ulnaris and superficial branch of ulnar nerve, and the recurrent branch of median nerve and comman digital nerve of the ring finger were measured, and the cross-sectional area was calculated. The number of nerve fiber was determined with HE staining and argentaffin staining. Results The crosssectional area and the number of nerve fiber were (2.46 ± 1.03) mm2 and 1 305 ± 239 for the profundus nervi ulnaris, (2.62 ± 1.75) mm2 and 1 634 ± 343 for the recurrent branch of median nerve, (1.60 ± 1.39) mm2 and 1 201 ± 235 for the superficial branch of ulnar nerve, and (2.19 ± 0.89) mm2 and 1 362 ± 162 for the comman digital nerve of the ring finger. There were no significant differences (P gt; 0.05) in the cross-sectional area and the number of nerve fiber between the profundus nervi ulnaris and the recurrent branch of median nerve, between the superficial branch of ulnar nerve and the comman digital nerve of the ring finger; and two factors had a l inear correlation (P lt; 0.05) with correlation coefficients of 0.68, 0.66 and 0.56, 0.36. The distances were (36.98 ± 4.93) mm from pisiform bone to the start point of the recurrent branch of median nerve, and (28.35 ± 6.63) mm to the start point of comman digital nerve of the ring finger. Conclusion Low end-to-side anastomosis of median nerve and ulnar nerve has perfect match in the cross-sectional area and the number of nerve fiber.
Objective To study and compare the effect of end-to-end and end-to-side neurorrhaphy between the reci pient’s musculocutaneous nerve and the donor’s ulnar nerve, and to observe the regeneration of peri pheral nerve and muscle refection. Methods Sixty male SD rats (weighing 200-250 g) were randomized into 2 groups (n=30 per group), and made the musculocutaneous nerve injury model. In group A, the donor’s nerve was transected for end-to-end neurorrhaphy.In group B, an epineurial window was exposed and the distal end of the muscle branch of musculocutaneous nerve was sutured to the side of the ulnar nerve. Electromyography was performed, biceps wet weight ratio, muscle fiber cross-sectional area, and count of myel inated nerve fiber (CMF) were measured at 4 and 12 weeks postoperatively. The behavior changes of the rats were observed. Results At 4 weeks, the nerve conduction velocity (NCV) and the latency ampl itude (AMP) of group A were significantly higher than those of group B (P lt; 0.05); at 12 weeks, there was no significant difference in the NCV and AMP between groups A and B (P gt; 0.05). At 4 and 8 weeks, there was no significant difference in biceps wet weight ratio and muscle fiber cross-sectional area between groups A and B (P gt; 0.05). At 4 weeks, the CMF was 230.15 ± 60.25 in group A and 160.73 ± 48.77 in group B, showing significant difference (P lt; 0.05); at 12 weeks, it was 380.26 ± 10.01 in group A and 355.63 ± 28.51 in group B, showing no significant difference (P gt; 0.05). Conclusion Both end-to-end and end-to-side neurorrhaphy have consistent long-term effect in repair of brachial plexus upper trunk injury.
Objective To recover the loss of the shoulder and elbow function after superior trunks injury of brachial plexus through multi ple nerves branch transfer simultaneously near the nerve entering points of reci pient nerves. Methods Four male patients (aged 21-39 years) with superior trunks injury of brachial plexus were treated from February to September 2007. All cases were injured in the traffic accident, left side in 1 case and right side in 3 cases, resulting in the loss of shoulder abduction, shoulder extorsion, shoulder l ift and elbow flexion, and the increase of muscle strength of shoulder shrug, elbow extension and finger flexion to above or equal to 4th grade. Patients were hospital ized 3-11 months afterinjury. Electromyography showed that the functions of accessory nerve, ulnar nerve and the branch to long head of tricepsbrachii were good, but the function of median nerve was injured partially. The following multiple donor nerves transfer were performed under general anaesthesia, namely from posterior approach accessory nerve to suprascapular nerve, from triceps to axillary nerve, from the partial branch of ulnar nerve to the biceps and/or brachial is muscular branch of musculocutaneous nerve. Results All incisions healed by first intention. One case suffered postoperative numbness on the ulnar side of hand and was symptomatically rel ieved after expectant treatment, while 3 cases had no manifestation of the motor and sensory functional injury related to donor nerve. All patients were followed up for 7-12 months. All patients regained the shoulder abduction and the elbow flexion 3-4 months after operation and electromyography showed that there was the regenerative potential in 3 recipient muscles. The shoulder abduction, elbow flexion and the muscle strength of the patients was 30-65°, 90-120° and 3-4 grade, respectively, 6-7 months after operation. Twelve months after operation, the first patient’s shoulder abduction, external rotation, superduction and elbow flexion almost returned to normal, and his shape of triangular muscle and biceps muscle were nearly normal. Conclusion Adopting donor nerves with similar functions to conduct the multiple donor nerves transfer in cord level has the advantages of l ittle functional loss at the donor sites, and fast and sound functional recovery at the reci pient sites. It is especially suitable for the superior trunks injury patient with delayed treatment and for the patient with the great risk in supraclavicular exploration, providing a new approach for treating superior trunks injury of brachial plexus.
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 evaluate the feasibil ity of direct anastomosis in the rat model of the brachial plexus extravertebral foramen nerve root division of C5-7. Methods Forty-eight SD rats (male or female) aging 4-6 months and weighing 250-300 g were selected to make the model of extravertebral foramen nerve root division of C5-7. The left C5-7 nerve roots, as the experimental sides, were separated to the brachial plexus nerve trunk and the transected roots were sutured to theproximal stump immediately after cutting off the brachial plexus extravertebral foramen nerve root division. The right C5-7nerve roots, as the control sides, received no operation. The general condition of rats after operation was observed. The gross observation, the histological observation and BDA nerve tracing technology were adopted to observe the wet weight of musculus biceps brachii, the cross section of biceps brachii and the spinal cord and distal nerve trunk at 3 weeks, 3 months and 6 months after operation. Results All rats survived well after operation. Claudication and unfold claw reflex were observed in the experimental sides, and the unfold claw reflex disappeared 3 months later. Comparatively, the control sides were normal. Nerve adhesion aggravated gradually and the neural stems were shriveled within 6 months after operation in the experimental sides. Comparatively, the control sides were normal. The wet weight of biceps brachii in the experimental sides and the control sides at 3 weeks, 3 months and 6 months after operation was (0.28 ± 0.12), (1.37 ± 0.33), (0.58 ± 0.10), (1.36 ± 0.35), (1.39 ± 0.31), (1.37 ± 0.38) g, respectively, indicating significant differences between two sides at 3 weeks and 3 months (P lt; 0.05), but no significant difference at 6 months (P gt; 0.05). The modified Marsland and the LFB staining of spinal cord and superior trunk of brachial plexus showed that the number of neurons, cell nuclear and Nissl body decreased and cell bodies changed from swell ing to shrinkage, dyeing nerve fibers increased, neural axone was thin and myel in sheath was sl ightly stained at each time point in experimental side. The number of motor neurons in cornu anterius medullae spinal is in the experimental side was 84.5% ± 3.2%, 74.4% ± 4.5%, 73.7% ± 3.8% of that in the control side at each time point, respectively. HE staining of biceps brachii detected thatthe muscle denaturation was very serious at 3 months after operation and then recovered. Neural tracing used BDA showed that the closer to the proximal of nerve trunk, the more obviously stained it was of myel in sheath and the more massive of axon at 6 months after operation. And there was almost no myel in and axon stained in musculocutaneous nerve. Conclusion In the rat model of brachial plexus extravertebral foramen nerve root division, the motoneuron in cornu anterius medullae spinal is necrosis rate reaches 20%-30%, and most of the residual neurons are pathologic. The regenerated fibers manifest as insufficient dynamic power and incomplete development, making no sense for the recovery of end organ function. Therefore, the exact mechanism of the recovery of biceps brachial muscle demands further study.
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.