感觉系统
神经假体
神经再支配
神经假体
神经科学
接口(物质)
感官替代
光遗传学
脑-机接口
物理医学与康复
人机交互
认知
心理学
计算机科学
医学
气泡
并行计算
最大气泡压力法
脑电图
作者
Bao Tram Nghiem,Ian C. Sando,R. Brent Gillespie,Bryan McLaughlin,Gregory J. Gerling,Nicholas B. Langhals,Melanie G. Urbanchek,Paul S. Cederna
标识
DOI:10.1097/prs.0000000000001289
摘要
Each year, approximately 185,000 Americans suffer the devastating loss of a limb. The effects of upper limb amputations are profound because a person's hands are tools for everyday functioning, expressive communication, and other uniquely human attributes. Despite the advancements in prosthetic technology, current upper limb prostheses are still limited in terms of complex motor control and sensory feedback. Sensory feedback is critical to restoring full functionality to amputated patients because it would relieve the cognitive burden of relying solely on visual input to monitor motor commands and provide tremendous psychological benefits. This article reviews the latest innovations in sensory feedback and argues in favor of peripheral nerve interfaces. First, the authors examine the structure of the peripheral nerve and its importance in the development of a sensory interface. Second, the authors discuss advancements in targeted muscle reinnervation and direct neural stimulation by means of intraneural electrodes. The authors then explore the future of prosthetic sensory feedback using innovative technologies for neural signaling, specifically, the sensory regenerative peripheral nerve interface and optogenetics. These breakthroughs pave the way for the development of a prosthetic limb with the ability to feel.
科研通智能强力驱动
Strongly Powered by AbleSci AI