利用神经入肌点定位肩胛下肌痉挛的阻滞靶点

doi:10.16098/j.issn.0529-1356.2018.04.010

解剖学报 ›› 2018, Vol. 49 ›› Issue (4): 475-479.doi: 10.16098/j.issn.0529-1356.2018.04.010

利用神经入肌点定位肩胛下肌痉挛的阻滞靶点

田旭锋¹胡双江¹ 杨胜波^2*

1.遵义医学院第一附属医院影像科; 2.遵义医学院人体解剖学教研室，贵州遵义 563099

收稿日期:2017-06-12 修回日期:2017-10-23 出版日期:2018-08-06 发布日期:2018-08-06
通讯作者: 杨胜波 E-mail:yangshengbo8205486@163.com
基金资助:
利用肌外神经入肌点和肌内神经末梢密集区定位脑卒中肌痉挛的治疗靶点;利用肌内、外运动点定位脑卒中患者高发痉挛肌的阻滞靶点

Using the nerve entry point as the blocking target for the subscapularis muscle spasticity

TIAN Xu-feng¹HU Shuang-jiang¹ YANG Sheng-bo^2*

1.Department of Radiology, the First Affiliated Hospital of Zunyi Medical College; 2.Department of Anatomy, Zunyi Medical College, Guizhou Zunyi563099, China

Received:2017-06-12 Revised:2017-10-23 Online:2018-08-06 Published:2018-08-06
Contact: YANG Sheng-bo E-mail:yangshengbo8205486@163.com

摘要/Abstract

摘要：

目的准确定位肩胛下肌神经入肌点（NEP）的体表位置和穿刺深度，为实现肩胛下肌痉挛乙醇或苯酚注射的化学神经溶解术提供指导。方法 20具中国成年人尸体，仰卧。紧贴皮肤连接颈静脉切迹最下点与肩峰尖和颈静脉切迹最下点与剑胸结合处的曲线分别为NEP的横向参考线（H线）和纵向参考线（L线）。解剖暴露肩胛下肌各神经肌支的NEP，涂抹硫酸钡，螺旋计算机断层扫描（CT）与三维重建。Syngo系统下确定NEP在体表的投影点（P），P通过NEP投射至背部皮肤上的P’点；经P的垂线与H线、经P的水平线与L线的交点分别记为P_H和P_L，测量P_H和P_L在H和L线上的百分位置及NEP的深度。结果肩胛下肌上神经支和下神经支的P_H分别位于H线的（46.89±2.73）%和（42.56±2.59）%处，P_L分别位于L线的（7.58±2.88）%和（17.42±3.31）%处；NEP深度分别位于PP’线的（16.32±2.52）%和（29.93±2.89）%处。结论上述结果可为提高肩胛下肌痉挛化学神经溶解术的疗效和效率提供指导。

关键词: 肩胛下肌, 肌痉挛, 神经入肌点, 定位, 螺旋计算机断层扫描, 人

Abstract:

Objective This study is aimed to accurately localize the nerve entry point (NEP) of the subscapalaris muscle, and to provide guidance for implementing the chemical neurolysis of the ethanol or phenol injection for the treatment of subscapalaris muscle spasticity. Methods Twenty Chinese adult cadavers in the supine position were examined. The joining lines from the most inferior point of the jugular notch to the apex of the acromion and from the most inferior point of the jugular notch to the junction of sternal body and xiphoid process were designated as the horizontal (H line) and the longitudinal (L line) reference lines of the NEP, respectively. The cadavers were dissected to expose the NEPs of muscular branches of subscapalaris muscle.The NEPs were marked by barium sulfate. Spiral CT scanning and three-dimensional reconstruction were performed. The body surface projection points (P) of the NEPs were determined under Syngo system, P by N projecting to the back skin was designated as P’. The intersections after the vertical P and the H line, after the horizontal P and L line were designated as P_H and P_L, respectively. The percentage location of P_H and P_L points on H line and L line and depth of NEPs were measured respectively. Results The points P_H of the upper branch and lower branch of subscapular muscle were located at (78.49±5.48)% and (86.17±1.68)% of the H line, and at (21.94±3.59)% and (30.00±1.79)% of the L line, respectively. The depth of NEPs was located at (46.65±2.74)% or (45.87±2.39)%, respectively. Conclusion These results provide guidance for improving the efficacy and efficiency of the chemical neurolysis of the subscapalaris muscle spasticity.

Key words: Subscapalaris muscle, Spasticity, Nerve entry points, Localization, Spiral computed tomography, Human

田旭锋胡双江杨胜波. 利用神经入肌点定位肩胛下肌痉挛的阻滞靶点[J]. 解剖学报, 2018, 49(4): 475-479.

TIAN Xu-feng HU Shuang-jiang YANG Sheng-bo. Using the nerve entry point as the blocking target for the subscapularis muscle spasticity[J]. Acta Anatomica Sinica, 2018, 49(4): 475-479.

参考文献

［1］ Lee KW, Kim SB, Lee JH, et al. Effect of upper extremity robot-assisted exercise on spasticity in stroke patients ［J］. Ann Rehabil Med, 2016, 40(6):961-971.

［2］ Maneyapanda MB, McCormick ZL, Marciniak C, et al. Long-term dosing of intrathecal baclofen in the treatment of spasticity after acquired brain injury ［J］. PMR, 2017, S1934-1482(17):30020-30025.

［3］ Ryu Y, Ogata T, Nagao M, et al. The swimming test is effective for evaluating spasticity after contusive spinal cord injury ［J］. PLoS One, 2017, 12(2):e0171937.

［4］ Warden JM, Roberts SL, Chang Y, et al. Neuromuscular partitioning of subscapularis based on intramuscular nerve distribution patterns: implications for botulinum toxin injections ［J］. Arch Phys Med Rehabil, 2014, 95(7):1408-1415.

［5］ Bender L, McKenna K. Hemiplegic shoulder pain: defining the problem and its management ［J］. Disabil Rehabil, 2001, 23(16):698-705.

［6］ Hu ShY, Zhuo LF, Yang ShB. Using the nerve entry points to localize the nerve block targets of the triceps surae muscle spasticity ［J］. Chinese Journal of Clinical Anatomy, 2017, 35 (1):15-18.(in Chinese)

胡帅宇，卓力凡，杨胜波．利用神经入肌点定位小腿三头肌痉挛的神经阻滞靶点［J］．中国临床解剖学杂志，2017，35（1）：15-18.

［7］ Rasool G, Afsharipour B, Suresh N, et al. Spatial analysis of multichannel surface EMG in hemiplegic stroke ［J］. IEEE Trans Neural Syst Rehabil Eng, 2017, 25(10):1802-1811.

［8］ Lam K, Wong D, Tam CK, et al. Ultrasound and electrical stimulator-guided obturator nerve block with phenol in the treatment of hip adductor spasticity in long-term care patients: a randomized, triple blind, placebo controlled study ［J］. J Am Med Dir Assoc, 2015,16(3):238-246.

［9］ Picelli A, Dambruoso F, Bronzato M, et al. Efficacy of therapeutic ultrasound and transcutaneous electrical nerve stimulation compared with botulinum toxin type A in the treatment of spastic equinus in adults with chronic stroke: a pilot randomized controlled trial ［J］. Top Stroke Rehabil, 2014, 21(Suppl 1):8-16.

［10］ Chiodo A, Goodmurphy C, Haig A. Cadaveric study of methods for subscapularis muscle needle insertion ［J］. Am J Phys Med Rehabil, 2005, 84(9):662-665.

［11］ Lui J, Sarai M, Mills PB. Chemodenervation for treatment of limb spasticity following spinal cord injury: a systematic review ［J］. Spinal Cord, 2015, 53(4):252-264.

［12］ Hu ShJ, Tian XF, Zhang Y, et al. Extramuscular nerve block targets localization for the treatment of spasticity of the medial group of the muscles of the thigh ［J］. Acta Anatomica Sinica, 2015, 46 (4):532-537.(in Chinese)

胡双江，田旭峰，张永，等．大腿肌内侧群痉挛肌外神经阻滞靶点的定位［J］．解剖学报，2015，46(4)：532-537．

［13］ Larrazet S, Joste R, Stefan A, et al. Hemiplegic shoulder pain: comparison of two sites of intramuscular injections of botulinum toxin type A, “epautox” study ［J］. Ann Phys Rehabil Med, 2016, 59S:e72.

［14］ Hara T, Abo M, Hara H, et al. Effects of botulinum toxin A therapy and multidisciplinary rehabilitation on upper and lower limbspasticity in post-stroke patients ［J］. Int J Neurosci, 2017, 127(6):469-478.

［15］ Harrison TP, Sadnicka A, Eastwood DM. Motor points for the neuromuscular blockade of the subscapularis muscle ［J］. Arch Phys Med Rehabil, 2007, 88(3):295-297.

［16］ Perotto AO. Anatomical Guide for The Electromyographer: The Limbs and Trunk ［M］. 3rd ed. Springfield: CC Thomas, 1994:1-309.

［17］ Uchikawa K, Toikawa H, Liu M. Subscapularis motor point block for spastic shoulders in patients with cervical cord injury ［J］. Spinal Cord, 2009, 47(3):249-251.

［18］ Chironna RL, Hecht JS. Subscapularis motor point block for the painful hemiplegic shoulder ［J］. Arch Phys Med Rehabil, 1990, 71(6):428-429.

［19］ Hecht JS. Subscapular nerve block in the painful hemiplegic shoulder ［J］. Arch Phys Med Rehabil, 1992, 73(11): 1036-1039.

［20］ Bi Sh, Luo YK, Wang YX, et al. Ultrasound-guided injection of botulinum toxin to subscapular muscle by lateral (axillary) approach ［J］. Chinese Journal of Rehabilitation Medicine, 2012, 27(5):420-422.(in Chinese)

毕胜，罗渝昆，王月香，等.超声引导下的肩胛下肌外侧（腋下）入路肉毒毒素注射［J］.中国康复医学杂志，2012，27（5）：420-422.

［21］ Chiodo A, Goodmurphy C, Haig A. Cadaveric study of methods for subscapularis muscle needle insertion ［J］. Am J Phys Med Rehabil, 2005, 84(9):662-665.

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利用神经入肌点定位肩胛下肌痉挛的阻滞靶点

Using the nerve entry point as the blocking target for the subscapularis muscle spasticity

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