Cortical control of a prosthetic arm for self-feeding

被引：0

作者：

Meel Velliste

Sagi Perel

M. Chance Spalding

Andrew S. Whitford

Andrew B. Schwartz

机构：

[1] School of Medicine,Department of Neurobiology

[2] E1440 BST,Department of Bioengineering

[3] Lothrop Street,Department of Physical Medicine and Rehabilitation

[4] University of Pittsburgh,undefined

[5] Pittsburgh,undefined

[6] Pennsylvania 15213,undefined

[7] USA,undefined

[8] 749 Benedum Hall,undefined

[9] University of Pittsburgh,undefined

[10] Pittsburgh,undefined

[11] Pennsylvania 15261,undefined

[12] USA,undefined

[13] Center for the Neural Basis of Cognition,undefined

[14] University of Pittsburgh and Carnegie Mellon University,undefined

[15] Pittsburgh,undefined

[16] Pennsylvania 15213,undefined

[17] USA,undefined

[18] University of Pittsburgh,undefined

[19] Pittsburgh,undefined

[20] Pennsylvania 15213,undefined

[21] USA,undefined

[22] McGowan Institute for Regenerative Medicine,undefined

[23] University of Pittsburgh,undefined

[24] Pittsburgh,undefined

[25] Pennsylvania 15219,undefined

[26] USA,undefined

[27] Robotics Institute,undefined

[28] Carnegie Mellon University,undefined

[29] Pittsburgh,undefined

[30] Pennsylvania 15213,undefined

[31] USA,undefined

来源：

Nature | 2008年 / 453卷

关键词：

D O I：

暂无

中图分类号：

学科分类号：

摘要：

Brain-machine interfaces have mostly been used previously to move cursors on computer displays. Now experiments on macaque monkeys show that brain activity signals can control a multi-jointed prosthetic device in real-time. The monkeys used motor cortical activity to control a human-like prosthetic arm in a self-feeding task, with a greater sophistication of control than previously possible. This work could be important for the development of more practical neuro-prosthetic devices in the future.

引用

页码：1098 / 1101

页数：3

共 79 条

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[30] Moore MM(undefined)undefined undefined undefined undefined-undefined

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