期刊
MEDICAL & BIOLOGICAL ENGINEERING & COMPUTING
卷 42, 期 3, 页码 394-406出版社
SPRINGER HEIDELBERG
DOI: 10.1007/BF02344716
关键词
conduction block; alternating current; depolarisation; high frequency
类别
资金
- NIBIB NIH HHS [8R01-EB-002091] Funding Source: Medline
High-frequency alternating current (AC) waveforms have been shown to produce a quickly reversible nerve block in animal models, but the parameters and mechanism of this block are not well understood. A frog sciatic nervel gastrocnemius muscle preparation was used to examine the parameters for nerve conduction block in vivo, and a computer simulation of the nerve membrane was used to identify the mechanism for block. The results indicated that a 100% block of motor activity can be accomplished with a variety of waveform parameters, including sinusoidal and rectangular waveforms at frequencies from 2kHz to 20kHz. A complete and reversible block was achieved in 34 out of 34 nerve preparations tested. The most efficient waveform for conduction block was a 3-5kHz constant-current biphasic sinusoid, where block could be achieved with stimulus levels as low as 0.01 muCphase(-1). It was demonstrated that the block was not produced indirectly through fatigue. Computer simulation of high-frequency AC demonstrated a steady-state depolarisation of the nerve membrane, and it is hypothesised that the conduction block was due to this tonic depolarisation. The precise relationship between the steady-state depolarisation and the conduction block requires further analysis. The results of this study demonstrated that high-frequency AC can be used to produce a fast-acting, and quickly reversible nerve conduction block that may have multiple applications in the treatment of unwanted neural activity.
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