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表面肌电信号控制组织工程化骨骼肌在夹持工具上的自主运动。

Voluntary movement controlled by the surface EMG signal for tissue-engineered skeletal muscle on a gripping tool.

机构信息

Department of Bio-Application and Systems Engineering, Tokyo University of Agriculture and Technology, Tokyo, Japan.

出版信息

Tissue Eng Part A. 2013 Aug;19(15-16):1695-703. doi: 10.1089/ten.TEA.2012.0421. Epub 2013 Jun 11.

DOI:10.1089/ten.TEA.2012.0421
PMID:23444880
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3700140/
Abstract

We have developed a living prosthesis consisting of a living muscle-powered device, which is controlled by neuronal signals to recover some of the functions of a lost extremity. A tissue-engineered skeletal muscle was fabricated with two anchorage points from a primary rat myoblast cultured in a collagen Matrigel mixed gel. Differentiation to the skeletal muscle was confirmed in the tissue-engineered skeletal muscle, and the contraction force increased with increasing frequency of electric stimulation. Then, the tissue-engineered skeletal muscle was assembled into a gripper-type microhand. The tissue-engineered skeletal muscle of the microhand was stimulated electrically, which was then followed by the voluntary movement of the subject's hand. The signal of the surface electromyogram from a subject was processed to mimic the firing spikes of a neuromuscular junction to control the contraction of the tissue-engineered skeletal muscle. The tele-operation of the microhand was demonstrated by optical microscope observations.

摘要

我们开发了一种由活体肌肉驱动装置组成的活体假体,它可以通过神经元信号来恢复失去肢体的部分功能。组织工程骨骼肌是由在胶原基质胶混合凝胶中培养的原代大鼠成肌细胞培养的两个锚固点制成的。在组织工程骨骼肌中证实了向骨骼肌的分化,并且随着电刺激频率的增加收缩力增加。然后,将组织工程骨骼肌组装成夹型微型手。微型手的组织工程骨骼肌进行电刺激,然后跟随受试者手部的自主运动。从受试者的表面肌电图信号进行处理,以模拟运动神经元的发放尖峰来控制组织工程骨骼肌的收缩。通过光学显微镜观察演示了微型手的遥控操作。

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