Cut wires: The Electrophysiology of Regenerated Tissue.

Alexis L Lowe, Nitish V Thakor
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引用次数: 0

Abstract

When nerves are damaged by trauma or disease, they are still capable of firing off electrical command signals that originate from the brain. Furthermore, those damaged nerves have an innate ability to partially regenerate, so they can heal from trauma and even reinnervate new muscle targets. For an amputee who has his/her damaged nerves surgically reconstructed, the electrical signals that are generated by the reinnervated muscle tissue can be sensed and interpreted with bioelectronics to control assistive devices or robotic prostheses. No two amputees will have identical physiologies because there are many surgical options for reconstructing residual limbs, which may in turn impact how well someone can interface with a robotic prosthesis later on. In this review, we aim to investigate what the literature has to say about different pathways for peripheral nerve regeneration and how each pathway can impact the neuromuscular tissue's final electrophysiology. This information is important because it can guide us in planning the development of future bioelectronic devices, such as prosthetic limbs or neurostimulators. Future devices will primarily have to interface with tissue that has undergone some natural regeneration process, and so we have explored and reported here what is known about the bioelectrical features of neuromuscular tissue regeneration.

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断线:再生组织的电生理学。
当神经因创伤或疾病而受损时,它们仍然能够发出来自大脑的电子指令信号。此外,那些受损的神经具有部分再生的先天能力,因此它们可以从创伤中愈合,甚至可以重新支配新的肌肉目标。对于通过手术重建受损神经的截肢者来说,再生神经肌肉组织产生的电信号可以通过生物电子学来感知和解释,以控制辅助设备或机器人假肢。没有两个截肢者会有完全相同的生理机能,因为重建残肢有很多手术选择,这反过来可能会影响人们以后与机器人假肢的配合程度。在这篇综述中,我们的目的是研究文献中关于周围神经再生的不同途径以及每种途径如何影响神经肌肉组织的最终电生理。这一信息很重要,因为它可以指导我们规划未来生物电子设备的发展,如假肢或神经刺激器。未来的设备将主要与经历过一些自然再生过程的组织相连接,因此我们在这里探索并报告了神经肌肉组织再生的生物电特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
6.90
自引率
0.00%
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审稿时长
8 weeks
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