Is it necessary to use the entire root as a donor when transferring contralateral C7 nerve to repair median nerve？

If a partial contralateral C7 nerve is transferred to a recipient injured nerve, results are not satisfactory. However, if an entire contralateral C7 nerve is used to repair two nerves, both recipient nerves show good recovery. These findings seem contradictory, as the above two methods use the same donor nerve, only the cutting method of the contralateral C7 nerve is different. To verify whether this can actually result in different repair effects, we divided rats with right total brachial plexus injury into three groups. In the entire root group, the entire contralateral C7 root was transected and transferred to the median nerve of the affected limb. In the posterior division group, only the posterior division of the contralateral C7 root was transected and transferred to the median nerve. In the entire root ＋ posterior division group, the entire contralateral C7 root was transected but only the posterior division was transferred to the median nerve. After neurectomy,the median nerve was repaired on the affected side in the three groups. At 8, 12, and 16 weeks postoperatively, electrophysiological examination showed that maximum amplitude, latency, muscle tetanic contraction force, and muscle fiber cross-sectional area of the flexor digitorum superficialis muscle were significantly better in the entire root and entire root ＋ posterior division groups than in the posterior division group. No significant difference was found between the entire root and entire root ＋ posterior division groups. Counts of myelinated axons in the median nerve were greater in the entire root group than in the entire root ＋ posterior division group, which were greater than the posterior division group. We conclude that for the same recipient nerve, harvesting of the entire contralateral C7 root achieved significantly better recovery than partial harvesting, even if only part of the entire root was used for transfer. This result indicates that the entire root should be used as a donor when transferring contralateral C7 nerve.

Total brachial plexus injury： contralateral C7 root transfer to the lower trunk versus the median nerve

Contralateral C7（cC7） root transfer to the healthy side is the main method for the treatment of brachial plexus root injury. A relatively new modification of this method involves cC7 root transfer to the lower trunk via the prespinal route. In the current study, we examined the effectiveness of this method using electrophysiological and histological analyses. To this end, we used a rat model of total brachial plexus injury, and cC7 root transfer was performed to either the lower trunk via the prespinal route or the median nerve via a subcutaneous tunnel to repair the injury. At 4, 8 and 12 weeks, the grasping test was used to measure the changes in grasp strength of the injured forepaw. Electrophysiological changes were examined in the flexor digitorum superficialis muscle. The change in the wet weight of the forearm flexor was also measured. Atrophy of the flexor digitorum superficialis muscle was assessed by hematoxylin-eosin staining. Toluidine blue staining was used to count the number of myelinated nerve fibers in the injured nerves. Compared with the traditional method, cC7 root transfer to the lower trunk via the prespinal route increased grasp strength of the injured forepaw, increased the compound muscle action potential maximum amplitude, shortened latency, substantially restored tetanic contraction of the forearm flexor muscles, increased the wet weight of the muscle, reduced atrophy of the flexor digitorum superficialis muscle, and increased the number of myelinated nerve fibers. These findings demonstrate that for finger flexion functional recovery in rats with total brachial plexus injury, transfer of the cC7 root to the lower trunk via the prespinal route is more effective than transfer to the median nerve via subcutaneous tunnel.

Modified contralateral C7 nerve transfer: the possibility of permitting ulnar nerve recovery is confirmed by 10 cases of autopsy

Contralateral C7 nerve transfer surgery is one of the most important surgical techniques for treating total brachial plexus nerve injury. In the traditional contralateral C7 nerve transfer surgery, the whole ulnar nerve on the paralyzed side is harvested for transfer, which completely sacrifices its potential of recovery. In the present, novel study, we report on the anatomical feasibility of a modified contralateral C7 nerve transfer surgery. Ten fresh cadavers (4 males and 6 females) provided by the Department of Anatomy, Histology, and Embryology at the Medical College of Fudan University, China were used in modified contralateral C7 nerve transfer surgery. In this surgical model, only the dorsal and superficial branches of the ulnar nerve and the medial antebrachial cutaneous nerve on the paralyzed side (left) were harvested for grafting the contralateral (right) C7 nerve and the recipient nerves. Both the median nerve and deep branch of the ulnar nerve on the paralyzed (left) side were recipient nerves. To verify the feasibility of this surgery, the distances between each pair of coaptating nerve ends were measured by a vernier caliper. The results validated that starting point of the deep branch of ulnar nerve and the starting point of the medial antebrachial cutaneous nerve at the elbow were close to each other and could be readily anastomosed. We investigated whether the fiber number of donor and recipient nerves matched one another. The axons were counted in sections of nerve segments distal and proximal to the coaptation sites after silver impregnation. Averaged axon number of the ulnar nerve at the upper arm level was approximately equal to the sum of the median nerve and proximal end of medial antebrachial cutaneous nerve (left: 0.94:1;right: 0.93:1). In conclusion, the contralateral C7 nerve could be transferred to the median nerve but also to the deep branch of the ulnar nerve via grafts of the ulnar nerve without deep branch and the medial antebrachial cutaneous nerve. The advantage over traditional surgery was that the recovery potential of the deep branch of ulnar nerve was preserved. The study was approved by the Ethics Committee of Fudan University (approval number: 2015-064) in July, 2015.

Comparison between direct repair and humana cellular nerve allografting during contralateral C7 transfer to the upper trunk for restoration of shoulder abduction and elbow flexion

Direct coaptation of contralateral C7 to the upper trunk could avoid the interposition of nerve grafts. We have successfully shortened the gap and graft lengths, and even achieved direct coaptation. However, direct repair can only be performed in some selected cases, and partial procedures still require autografts, which are the gold standard for repairing neurologic defects. As symptoms often occur after autografting, human acellular nerve allografts have been used to avoid concomitant symptoms. This study investigated the quality of shoulder abduction and elbow flexion following direct repair and acellular allografting to evaluate issues requiring attention for brachial plexus injury repair. Fifty-one brachial plexus injury patients in the surgical database were eligible for this retrospective study. Patients were divided into two groups according to different surgical methods. Direct repair was performed in 27 patients, while acellular nerve allografts were used to bridge the gap between the contralateral C7 nerve root and upper trunk in 24 patients. The length of the harvested contralateral C7 nerve root was measured intraoperatively. Deltoid and biceps muscle strength, and degrees of shoulder abduction and elbow flexion were examined according to the British Medical Research Council scoring system;meaningful recovery was defined as M3–M5. Lengths of anterior and posterior divisions of the contralateral C7 in the direct repair group were 7.64 ± 0.69 mm and 7.55 ± 0.69 mm, respectively, and in the acellular nerve allografts group were 6.46 ± 0.58 mm and 6.43 ± 0.59 mm, respectively. After a minimum of 4-year follow-up, meaningful recoveries of deltoid and biceps muscles in the direct repair group were 88.89% and 85.19%, respectively, while they were 70.83% and 66.67% in the acellular nerve allografts group. Time to C5/C6 reinnervation was shorter in the direct repair group compared with the acellular nerve allografts group. Direct repair facilitated the restoration of shoulder abduction and elbow flexion. Thus, if direct coaptation is not possible, use of acellular nerve allografts is a suitable option. This study was approved by the Medical Ethical Committee of the First Affiliated Hospital of Sun Yat-sen University, China (Application ID:[2017] 290) on November 14, 2017.

Contralateral C7 transfer combined with acellular nerve allografts seeded with differentiated adipose stem cells for repairing upper brachial plexus injury in rats

Nerve grafting has always been necessary when the contralateral C7 nerve root is transferred to treat brachial plexus injury. Acellular nerve allograft is a promising alternative for the treatment of nerve defects, and results were improved by grafts laden with differentiated adipose stem cells. However, use of these tissue-engineered nerve grafts has not been reported for the treatment of brachial plexus injury. The aim of the present study was to evaluate the outcome of acellular nerve allografts seeded with differentiated adipose stem cells to improve nerve regeneration in a rat model in which the contralateral C7 nerve was transferred to repair an upper brachial plexus injury. Differentiated adipose stem cells were obtained from Sprague-Dawley rats and transdifferentiated into a Schwann cell-like phenotype. Acellular nerve allografts were prepared from 15-mm bilateral sections of rat sciatic nerves. Rats were randomly divided into three groups: acellular nerve allograft, acellular nerve allograft + differentiated adipose stem cells, and autograft. The upper brachial plexus injury model was established by traction applied away from the intervertebral foramen with micro-hemostat forceps. Acellular nerve allografts with or without seeded cells were used to bridge the gap between the contralateral C7 nerve root and C5–6 nerve. Histological staining, electrophysiology, and neurological function tests were used to evaluate the effect of nerve repair 16 weeks after surgery. Results showed that the onset of discernible functional recovery occurred earlier in the autograft group first, followed by the acellular nerve allograft + differentiated adipose stem cells group, and then the acellular nerve allograft group;moreover, there was a significant difference between autograft and acellular nerve allograft groups. Compared with the acellular nerve allograft group, compound muscle action potential, motor conduction velocity, positivity for neurofilament and S100, diameter of regenerating axons, myelin sheath thickness, and density of myelinated fibers were remarkably increased in autograft and acellular nerve allograft + differentiated adipose stem cells groups. These findings confirm that acellular nerve allografts seeded with differentiated adipose stem cells effectively promoted nerve repair after brachial plexus injuries, and the effect was better than that of acellular nerve repair alone. This study was approved by the Animal Ethics Committee of the First Affiliated Hospital of Sun Yat-sen University of China(approval No. 2016-150) in June 2016.

Proteomic analysis of trans-hemispheric motor cortex reorganization following contralateral C7 nerve transfer

Nerve transfer is the most common treatment for total brachial plexus avulsion injury. After nerve transfer, the movement of the injured limb may be activated by certain movements of the healthy limb at the early stage of recovery, i.e., trans-hemispheric reorganization. Pre- vious studies have focused on functional magnetic resonance imaging and changes in brain-derived neurotrophic factor and growth asso- ciated protein 43, but there have been no proteomics studies. In this study, we designed a rat model of total brachial plexus avulsion injury involving contralateral C7 nerve transfer. Isobaric tags for relative and absolute quantitation and western blot assay were then used to screen differentially expressed proteins in bilateral motor cortices. We found that most differentially expressed proteins in both cortices of upper limb were associated with nervous system development and function （including neuron differentiation and development, axonogenesis, and guidance）, microtubule and cytoskeleton organization, synapse plasticity, and transmission of nerve impulses. Two key differentially expressed proteins, neurofilament light （NFL） and Thy-1, were identified. In contralateral cortex, the NFL level was upregulated 2 weeks after transfer and downregulated at 1 and 5 months. The Thy-1 level was upregulated from 1 to 5 months. In the affected cortex, the NFL level increased gradually from 1 to 5 months. Western blot results of key differentially expressed proteins were consistent with the proteom- ic findings. These results indicate that NFL and Thy-1 play an important role in trans-hemispheric organization following total brachial plexus root avulsion and contralateral C7 nerve transfer.

Evaluation of nerve transfer options for treating total brachial plexus avulsion injury： a retrospective study of 73 participants

Despite recent great progress in diagnosis and microsurgical repair, the prognosis in total brachial plexus-avulsion injury remains unfavorable.Insufficient number of donors and unreasonable use of donor nerves might be key factors. To identify an optimal treatment strategy for this condition, we conducted a retrospective review. Seventy-three patients with total brachial plexus avulsion injury were followed up for an average of 7.3 years. Our analysis demonstrated no significant difference in elbow-flexion recovery between phrenic nerve-transfer （25 cases）, phrenic nerve-graft （19 cases）, intercostal nerve （17 cases）, or contralateral C7-transfer （12 cases） groups. Restoration of shoulder function was attempted through anterior accessory nerve （27 cases）, posterior accessory nerve （10 cases）, intercostal nerve （5 cases）, or accessory ＋ intercostal nerve transfer （31 cases）. Accessory nerve ＋ intercostal nerve transfer was the most effective method. A significantly greater amount of elbow extension was observed in patients with intercostal nerve transfer （25 cases） than in those with contralateral C7 transfer （10 cases）. Recovery of median nerve function was noticeably better for those who received entire contralateral C7 transfer （33 cases） than for those who received partial contralateral C7 transfer （40 cases）. Wrist and finger extension were reconstructed by intercostal nerve transfer （31 cases）. Overall, the recommended surgical treatment for total brachial plexus-avulsion injury is phrenic nerve transfer for elbow flexion, accessory nerve ＋ intercostal nerve transfer for shoulder function, intercostal nerves transfer for elbow extension, entire contralateral C7 transfer for median nerve function, and intercostal nerve transfer for finger extension. The trial was registered at Clinical-Trials.gov （identifier： NCT03166033）.

正中及尺神经部分束早期移位治疗臂丛C5-7根性损伤的长期疗效观察

目的:分析正中及尺神经部分束早期移位治疗臂丛C5、C6、C7根性损伤中重建屈肘功能的长期疗效。方法:对11例臂丛C5-7根性损伤,确诊后早期施行神经移位术:正中神经部分束移位至肌皮神经的肱二头肌支、尺神经部分束移位至肱肌肌支,双重移位,重建屈肘功能。术中运用电生理技术,增加手术的合理性和准确性。并进行平均67.8个月的长期随访,按结果分析疗效。结果:优9例,良2例,屈肘功能恢复满意。6例于术后3个月肱二头肌、肱肌肌电图即能检出再生电位。一例术后6个月肱二头肌才检出再生电位,该病人于伤后8个月才施行手术。结论:臂丛C5-7根性损伤确诊后,早期正中及尺神经部分束双重移位是重建屈肘功能安全有效的方法,较之单一的尺神经束移位(Oberlin术式)提高了屈肘功能的修复效率,具有效果好、恢复快、操作简单的优点。

Contralateral C7 Nerve Root Transfer for Function Recovery in Adults： A Meta-analysis

Background：Root avulsion to all 5 roots of the brachial plexus is a common presentation and keeps a major reconstructive challenge.The contralateral C7 （CC7） nerve transfer has been used in treating brachial plexus avulsion injury （BPAI） since 1986.However,the effectiveness of the procedure remains a subject of controversy.The aim of this meta-analysis was to study surgical outcomes regarding motor and sensory recovery after CC7 nerve transfer.Methods：Chinese or English （i.e.,＂contralateral c-7＂,＂contralateral c7＂,＂c7 nerve root＂,and ＂seventh cervical nerve root＂） keywords were used for a literature search for articles related to CC7 nerve transfer in several databases （i.e.,PubMed,Cochrane,Embase,CNKI,CQVIP,and Wanfang Data）.Clinical research articles were screened,and animal studies as well as duplicate publications were excluded.Muscle strength and sensory recovery were considered to be effective only when the scores on the United Kingdom Medical Research Council scale were equal to or higher than M3 and S3,respectively.Results：The overall ipsilateral recipient nerve recovery rates were as follows：the efficiency rate for muscle strength recovery after CC7 nerve transfer was 0.57 （95% confidence interval [CI]：0.48-0.66） and for sensory recovery was 0.52 （95% CI：0.46-0.58）.When the recipient nerve was the median nerve,the efficiency rate for muscle strength recovery was 0.50 （95% CI：0.39-0.61） and for sensory was 0.56 （95% CI：0.50-0.63）.When the recipient nerve was the musculocutaneous nerve and the radial nerve,the efficiency rate for muscle strength recovery was 0.74 （95% CI：0.65-0.82） and 0.50 （95% CI：0.31-0.70）,respectively.Conclusions：Transfer of CC7 nerves to musculocutaneous nerves leads to the best results.CC7 is a reliable donor nerve,which can be safely used for upper limb function reconstruction,especially for entirely BPAI.When modifying procedures,musculocutaneous nerves and median nerve can be combined as recipient nerves.

Outcome of contralateral C7 nerve transferring to median nerve

Background Contralateral C7 （cC7） transfer had been widely used in many organizations in the world, but the outcomes were significantly different. So the purpose of the study was to evaluate the outcome of patients treated with cC7 transferring to median nerve and to determine the factors affecting the outcome of this procedure.

健侧颈7神经根经椎前路转位治疗外伤性臂丛神经损伤患者的护理

目的：探讨健侧颈7神经根经椎前路转位治疗外伤性臂丛神经损伤患者的护理方法。方法回顾性分析2006年1月至2012年12月在第二炮兵总医院骨科治疗的30例外伤所致臂丛神经损伤的患者的临床资料，所有患者均采用健侧颈7神经根经椎前路转位重建受损的臂丛神经，术前加强心理护理，术后注重肢体及支具护理及健康指导。结果患者术后恢复良好，经过1～2年随访，患者肌力增强。结论健侧颈7神经根经椎前路转位重建受损的臂丛神经效果较好，术后精心护理是患者早日康复的关键。

患侧颈_7神经根移位治疗产瘫根性撕脱伤

目的报道患侧C7神经根移位治疗根性撕脱伤性产瘫的临床效果。方法将患侧C7在中干前后股处切断并移位与上干或下干远端缝合,治疗单纯上干或下干根性撕脱伤的产瘫患儿11例,其中上干损伤9例,下干损伤2例。结果单纯上干损伤者优5例,良3例,中2例,差1例。单纯下干损伤者差2例。结论患侧C7神经根移位是治疗单纯上干根性撕脱伤产瘫的较好方法,值得应用推广,但对单纯下干损伤的产瘫效果较差。

早期神经移位治疗臂丛颈5-7根性损伤的长期疗效观察

目的分析早期移位桡神经三头肌肌支及副神经治疗臂丛颈5-7根性损伤中重建肩外展功能的长期疗效。方法臂丛颈5-7根性损伤11例,确诊后早期即施行神经移位术:桡神经肱三头肌长头支移位至腋神经的三角肌支、副神经移位至肩胛上神经,施行双重移位,同时重建冈上下肌与三角肌的功能。术中运用电生理技术,增加手术的准确性和合理性。并进行了平均67.8个月的长期随访,按结果分析疗效。结果优9例,良2例,肩外展功能恢复满意。6例在术后约3个月冈上下肌、三角肌电生理检查即可检出再生电位。结论臂丛颈5-7根性损伤确诊后,早期行副神经及肱三头肌肌支双重移位是重建肩外展功能安全有效的方法,提高了肩外展的修复效率。

健侧C_7神经根移位经椎体前通路的应用解剖及临床研究

目的 通过尸体解剖及临床手术 ,找到健侧C7神经移位修复臂丛损伤的最佳桥接神经通路。方法 对 8具成人颈段尸体标本 ,显露双侧臂丛神经 ,将右侧C7神经在干股交界处切断并游离至椎孔处 ,经前斜角肌的深面翻转至椎体前 ,测量C7神经根至对侧臂丛上干前后股的距离。临床选择 13例臂丛神经撕脱伤患者 ,术中测量健侧C7神经根经椎体前及颈前皮下通路修复患侧臂丛上干或前后股的距离 ,并对其手术入路进行观测。结果 尸体标本测量C7神经根经椎体前通路至对侧臂丛上干前后股的距离平均为 ( 7.9± 2 .6)cm , x±s,下同。临床测量健侧C7神经根经椎体前通路及颈前皮下通路至对侧臂丛上干或前后股的距离分别为 ( 9.4± 1.2 )cm及 ( 18.2± 3 .2 )cm。两组相比差异有显著意义 (P<0 .0 1)。临床应用 13例全部取得成功 ,无并发症出现。结论 经椎体前通路是健侧C7神经移位修复臂丛损伤的最佳桥接神经通路之一。

中断神经节与尺神经联系对健侧C_7神经根移位疗效影响的实验研究

目的 探讨中断C7～T1背根神经节与桥接尺神经联系对健侧C7神经根移位治疗全臂丛根性撕脱伤疗效的影响。方法 将 192只SD大鼠作成全臂丛根性撕脱伤模型。实验分为 3组。A组 :将患侧尺神经远端与健侧C7神经根缝合 ,其近端与正中神经缝合。B组 :将患侧尺神经远端与健侧C7神经根缝合 ,术后 6周将其近端与正中神经缝合。C组 :将患侧尺神经远端与健侧C7神经根缝合 ,同时切断患侧C7、8T1神经根 ,术后 6周将尺神经近端与正中神经缝合。 3组又分伤后即刻、1、2、4个月 4个手术时间组 ,每组 48只。 3组分别于术后 18、3 6周检测正中神经运动动作电位 (motoractionpotential ,CMAP)波幅、有髓神经纤维数及趾浅屈肌肌湿重、肌纤维截面积和肌张力 ,并计算它们的恢复率。结果 ( 1)损伤后早期手术 :C组大鼠各项检测指标均显著优于A、B组 (P <0 .0 1) ,而A组与B组差异不明显 (P >0 .0 5 )。 ( 2 )损伤后晚期手术 :B、C组各项检测指标均优于A组 (P <0 .0 1) ,而B组与C组之间差异无显著意义 (P >0 .0 5 )。结论 ( 1)全臂丛根性撕脱伤早期行健侧C7神经根移位 ,中断神经节与桥接尺神经的联系 ,能显著提高健侧C7神经根移位的疗效。 ( 2 )全臂丛根性撕脱伤晚期手术时 ,因尺神经已基本自然变性 。

带尺侧上副动脉尺神经转位的解剖及临床意义

目的 :为临床上带血管蒂的尺神经移植在健侧颈 7移位治疗臂丛根性撕脱伤中的应用提供解剖学依据。方法 :取新鲜经动脉灌注红色乳胶的成人上肢标本 2 2侧进行显微解剖 ,观察尺神经外部营养动脉的来源。另取患骨肿瘤而截肢新鲜成人上肢 6侧作仅保留尺侧上副动脉的尺神经游离 ,采用动脉灌注墨汁和尺神经组织切片的方法 ,观察尺侧上副动脉对尺神经内部血供营养的范围。结果 :尺神经在腋部由胸外侧或腋动脉的分支供应 ,在内侧肌间隔后方由尺侧上副动脉供应 ,在尺神经沟由尺侧上副动脉与尺侧返动脉后支的吻合支供应 ,在前臂由尺侧返动脉和尺动脉的分支供应。尺侧上副动脉灌注墨汁后 ,尺神经腕部、手背支及腋部的神经束内微血管被墨汁充填。结论 :以尺侧上副动脉的起始处为血管蒂部旋转点 ,尺神经可提供平均为 (46 .5± 2 .6 )cm的有血供的移植长度 ,可经胸前皮下隧道逆向转位与对侧颈 7神经根吻合。

两种健侧颈7移位下干的术式修复大鼠全臂丛神经损伤的疗效比较研究

目的 比较健侧颈7经颈椎前路直接移位于伤侧下干与健侧颈7通过游离神经移植桥接伤侧下干修复大鼠全臂丛神经损伤的疗效.方法 将90只成年Sprague Dawley大鼠随机分为三组,每组30只:A组(健侧颈7经颈椎前路直接移位伤侧下干组)、B组(健侧颈7-游离神经移植—伤侧下干组)和C组(健康对照组).设定左侧为伤侧,切断臂丛神经建造全臂丛神经损伤模型,按分组采用不同术式修复下干.比较三组大鼠术后4、8和12周的电生理检查、肌张力测试、肌纤维横截面积测量和神经纤维计数结果,评估两种术式对全臂丛损伤的下干修复效果.结果 神经电生理检查结果显示,术后A、B组尺侧腕屈肌与指浅屈肌复合肌肉动作电位潜伏期均测得一定程度的恢复,术后8、12周,A组潜伏期短于B组(P<0.05),A、B两组尺侧腕屈肌与指浅屈肌复合肌肉动作电位最大波幅比较,A组波幅大于B组,差异有统计学意义(P<0.05).肌张力测试结果显示,术后4、8、12周,A组前臂屈肌群肌张力恢复优于B组,但A、B组均小于C组,差异均有统计学意义(P<0.05).肌纤维横截面积测量结果显示,术后4、8、12周,A组尺侧腕屈肌和指浅屈肌横截面积大于B组,差异有统计学意义(P<0.05),但未恢复正常.神经纤维计数结果显示,术后8、12周,A组正中神经及尺神经纤维平均直径及总数均大于B组,差异有统计学意义(P<0.05),但未恢复正常.结论 健侧颈7通过游离神经移植桥接伤侧下干修复大鼠全臂丛神经损伤是可行的,从神经电生理、神经肌肉组织学检测结果可见恢复效果,但较健侧颈7经颈椎前路直接移位伤侧下干的修复效果差.

椎管内外神经根移位整体化治疗臂丛神经根性撕脱伤的实验研究

目的：研究臂丛神经根性撕脱伤后，椎管内、外神经根移位治疗臂丛神经根性撕脱伤的疗效。方法随机选取SD大鼠60只，随机分为实验组及对照组。实验组采用椎管内C5，C6神经根原位修复及健侧C7神经移位修复C8，T1神经根治疗臂丛根性撕脱伤；对照组为膈神经修复肌皮神经，副神经修复肩胛上神经，健侧C7移位修复C8，T1神经根治疗臂丛根性撕脱伤。术后6个月时取材，进行电生理检测，肌肉湿重的测量，肌肉纤维横截面积的检测，HE染色检测观察肌纤维数量，电镜观察神经纤维数量及神经直径。结果实验组神经损伤修复6个月时，其肌肉湿重、肌肉纤维横截面积、肌肉运动诱发电位恢复率、神经生长情况优于对照组。结论椎管内神经根原位修复及椎管外神经根移位整体化治疗臂丛神经根性撕脱伤，无论从肌肉湿重、还是肌肉纤维横截面积比率，或者肌肉运动诱发电位及再生神经生长情况等方面，都取得了良好的效果。

健侧C_7神经经椎体后通路治疗臂丛神经根性撕脱伤的解剖学研究

目的通过解剖学研究,探讨健侧C7神经经椎体后通路移位治疗对侧臂丛神经根性撕脱伤的可行性。方法取10具甲醛固定的成人尸体标本,其中男7具,女3具,标本均无明显畸形,组织无缺损,颈部中立位。模拟臂从神经损伤手术探查方式,将C_7神经根的前、后股向远端行干支分离使其长度增加后再切断,同时测量C_7神经根自椎间孔发出至分股处长度及其前、后股长度;模拟颈椎后路手术入路,充分暴露C_7颈椎及T_1棘突,并于其间靠近椎体侧钻孔,测最经椎体后通路达对侧臂丛神经上干与下干距离。结果 C_7神经根长度为(58.62±8.70)mm,加后股长度为(65.15±9.11)mm,加前股长度为(70.03±10.79)mm。经椎体后通路C_7神经根至对侧臂丛神经上干距离为(72.12±10.22)mm,至对侧臂丛神经下干距离为(95.21±12.50)mm。结论健侧C_7神经可以经椎体后通路移位至对侧,不需要或仅需一小段桥接神经,该通路能有效避免经椎体前路损伤血管、神经等并发症,可能成为治疗臂丛神经根性撕脱伤的有效入路。

手外科扎根临床不断创新

手外科以往在手指再造、皮瓣移植等领域取得了多项世界首创的辉煌成果。在顾玉东院士的领衔下,提出了以健侧颈7为代表的多项治疗臂丛神经损伤的手术策略,成为国际领先的周围神经损伤诊治中心。近十年来,我们聚焦神经损伤及修复后的脑功能重塑研究,揭示了健侧颈7移位后运动感觉中枢功能重塑的模式,发现了一侧半球可以同时支配双侧上肢的重要规律,并将此发现应用到中枢损伤后偏瘫患者的治疗中,将健侧颈7应用到更广泛的人群中,实现了将科研创新与临床实践相结合,手外科在创新中不断发展。