经胫骨截肢中的激动剂-拮抗剂肌神经界面

IF 16.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Accounts of Chemical Research Pub Date : 2023-08-24 eCollection Date: 2023-07-01 DOI:10.2106/JBJS.ST.22.00038
Colin J Harrington, Marissa Dearden, John Richards, Matthew Carty, Jason Souza, Benjamin K Potter
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引用次数: 0

摘要

背景:经胫骨截肢时的激动-拮抗肌神经接口(AMI)技术包括使用激动-拮抗肌对来恢复自然收缩-伸展关系,并在使用假肢时改善本体感觉反馈1:利用长肌筋膜后皮瓣的标准切口,解剖肢体的外侧和内侧,分别识别并保留腓浅神经和隐神经。在远端切断胫骨前肌腱和腓骨长肌腱,以便为 AMI 构建留出足够的长度。结扎胫前血管后,识别并标记腓深神经,以创建再生外周神经接口(RPNI)。在距内侧关节线约 15 厘米处切断胫骨和腓骨,以便于解剖深后室并结扎腓肠肌和胫骨后血管。在远端横断外侧腓肠肌和胫骨后肌腱,完成截肢。从残肢上获取伸肌缰绳和多块 2 × 3 厘米的游离肌肉移植物,这些肌肉将用于 RPNI 构建。用缝合锚将腓肠肌网固定在胫骨上,然后构建一对外侧腓肠肌和胫骨前肌以及胫骨后肌和腓骨长肌的 AMI。对主要的下肢神经分别进行 RPNI,并以标准的分层方式缝合伤口:理由:AMI 技术可在经胫骨截肢时恢复自然的激动肌-拮抗肌关系,从而增加本体感觉反馈并改善假肢控制。这些结果与传统的等长肌力矫正术形成鲜明对比,因为传统的等长肌力矫正术会阻止本体感觉从残肢肌肉组织传递到中枢神经系统。此外,AMI 技术允许肌肉进行同心和偏心收缩,这可能有助于保持肢体的体积并帮助安装假肢,而不是在标准经胫骨截肢后观察到的典型肢体萎缩1,2。随着更先进假肢的开发和供应,AMI 技术可提供更精确的控制,并增强这些创新设备的功能:AMI技术在经胫截肢术中的早期临床效果很好。在首批接受该手术的 3 名患者的系列病例中,并发症较少,仅有 2 例蜂窝组织炎和 1 例伤口延迟愈合1。与接受标准经胫截肢手术的患者相比,通过肌电图测量的肌肉活化情况表明,在尝试移动幻肢时,限制意外肌肉共收缩的能力有所提高1。此外,术后残肢的体积得以保持,无需对假肢进行大幅修改:胫骨前肌、腓骨长肌、胫骨后肌和外侧腓肠肌的肌腱应尽可能向远端横断,以留出足够的长度来创建 AMI 构架。从截肢肢体上采集约 2 × 3 厘米的游离肌肉移植物用于 RPNI3。在闭合前应确认肌腱顺利滑过滑膜隧道。必要时,肌肉剥离可改善滑行并减小残肢的大小。为滑膜隧道采集伸肌腱膜一直是我们的首选方法,尽管我们承认也有其他移植物可供选择,如跗骨隧道1:RPNI = 再生外周神经接口AMI = 激动-拮抗肌神经接口EMG = 肌电图。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Agonist-Antagonist Myoneural Interface in a Transtibial Amputation.

Background: The agonist-antagonist myoneural interface (AMI) technique at the time of transtibial amputation involves the use of agonist-antagonist muscle pairs to restore natural contraction-stretch relationships and to improve proprioceptive feedback when utilizing a prosthetic limb1.

Description: Utilizing the standard incision for a long posterior myofasciocutaneous flap, the lateral and medial aspects of the limb are dissected, identifying and preserving the superficial peroneal and saphenous nerve, respectively. The tendons of the tibialis anterior and peroneus longus are transected distally to allow adequate length for the AMI constructs. After ligation of the anterior tibial vessels, the deep peroneal nerve is identified and tagged to create a regenerative peripheral nerve interface (RPNI). The tibia and fibula are cut approximately 15 cm from the medial joint line, facilitating dissection of the deep posterior compartment and ligation of the peroneal and posterior tibial vessels. The tendons of the lateral gastrocnemius and tibialis posterior are transected distally, and the amputation is completed. The extensor retinaculum is harvested from the residual limb along with multiple 2 × 3-cm free muscle grafts, which will be used for the RPNI constructs. The retinaculum is secured to the tibia with suture anchors, and AMI pairs of the lateral gastrocnemius and tibialis anterior as well as the tibialis posterior and peroneus longus are constructed. Separate RPNIs of the major lower-extremity nerves are performed, and the wound is closed in a standard layered fashion.

Alternatives: An isometric myodesis of the gastrocnemius without coaptation of agonist-antagonist muscle pairs can be performed at the time of transtibial amputation.

Rationale: The AMI technique restores natural agonist-antagonist relationships at the time of transtibial amputation to increase proprioceptive feedback and improve prosthetic control. These outcomes contrast with those of a traditional isometric myodesis, which prevents proprioceptive communication from the residual limb musculature to the central nervous system. Additionally, the AMI technique allows for concentric and eccentric muscular contractions, which may contribute to the maintenance of limb volume and aid with prosthetic fitting, as opposed to the typical limb atrophy observed following standard transtibial amputation1,2. With the development and availability of more advanced prostheses, the AMI technique offers more precise control and increases the functionality of these innovative devices.

Expected outcomes: Early clinical outcomes of the AMI technique at the time of transtibial amputation have been promising. In a case series of the first 3 patients who underwent the procedure, complications were minor and consisted of 2 episodes of cellulitis and 1 case of delayed wound healing1. Muscle activation measured through electromyography demonstrated an improved ability to limit unintended muscular co-contraction with attempted movement of the phantom limb, as compared with patients who underwent a standard transtibial amputation1. Additionally, residual limb volume was maintained postoperatively without the need for substantial prosthetic modifications.

Important tips: The tendons of the tibialis anterior, peroneus longus, tibialis posterior, and lateral gastrocnemius should be transected as distal as possible to allow adequate length for creation of the AMI constructs.Approximately 2 × 3-cm free muscle grafts are harvested from the amputated extremity for RPNI3.Smooth tendon-gliding through the synovial tunnels should be confirmed before closure. If necessary, muscle debulking can improve gliding and decrease the size of the residual limb.Harvesting the extensor retinaculum for synovial tunnels has been our preferred method, although we acknowledge that other grafts options such as the tarsal tunnel are available1.

Acronyms & abbreviations: RPNI = regenerative peripheral nerve interfaceAMI = agonist-antagonist myoneural interfaceEMG = electromyographic.

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来源期刊
Accounts of Chemical Research
Accounts of Chemical Research 化学-化学综合
CiteScore
31.40
自引率
1.10%
发文量
312
审稿时长
2 months
期刊介绍: Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.
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