Title :
Real-time interaction between a neuromorphic electronic circuit and the spinal cord
Author :
Jung, Ranu ; Brauer, Elizabeth J. ; Abbas, James J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Kentucky Univ., Lexington, KY, USA
Abstract :
We present a novel demonstration of real-time dynamic interaction between an oscillatory spinal cord (isolated lamprey nervous system) and electronic hardware that mimics the spinal motor pattern generating circuitry. The spinal cord and the neuromorphic circuit were interfaced in unidirectional and bidirectional modes. Bidirectional coupling resulted in stable, persistent oscillations. This experimental platform offers a unique paradigm to examine the intrinsic dynamics of neural circuitry. The neuromorphic analog very large scale integration (aVLSI) design and real-time capabilities of this approach may provide a particularly powerful means of restoring complex neuromotor function using neuroprostheses.
Keywords :
VLSI; biocontrol; biomedical electronics; handicapped aids; limit cycles; neural chips; neuromuscular stimulation; prosthetics; bidirectional mode; complex neuromotor function restoration; dynamic interaction; intrinsic dynamics; isolated lamprey nervous system; limit cycles; neural circuitry; neuromorphic analog VLSI design; neuromorphic electronic circuit; neuroprostheses; real-time interaction; sensitivity analysis; spinal cord; spinal motor pattern generating circuitry; stable persistent oscillations; unidirectional mode; Biomedical engineering; Brain injuries; Control systems; Electronic circuits; Feedback circuits; Nervous system; Neuromorphics; Real time systems; Spinal cord; Very large scale integration; Animals; Computer Systems; Electric Stimulation Therapy; Lampreys; Locomotion; Motor Neurons; Muscle, Skeletal; Nerve Net; Neural Networks (Computer); Neuromuscular Junction; Prosthesis Design; Spinal Cord; User-Computer Interface;
Journal_Title :
Neural Systems and Rehabilitation Engineering, IEEE Transactions on
DOI :
10.1109/7333.948461
