计数周期法量化高频周围神经阻滞中的起始反应。

Counted cycles method to quantify the onset response in high-frequency peripheral nerve block.

作者信息

Foldes Emily L, Ackermann D, Bhadra Niloy, Kilgore Kevin L

机构信息

Dept. of Biomedical Engineering, Case Western Reserve University, Cleveland, OH, USA.

出版信息

Annu Int Conf IEEE Eng Med Biol Soc. 2009;2009:614-7. doi: 10.1109/IEMBS.2009.5332758.

DOI:10.1109/IEMBS.2009.5332758

PMID:19963719

Abstract

The clinical use of high frequency alternating current (HFAC) to block nerve conduction in peripheral nerves is limited due to the large volley of nerve activity generated at the initiation of HFAC. This "onset response" must be characterized in order to determine if it is possible to eliminate it. In this study, preliminary experiments were conducted in an in-vivo animal model using counted cycles of HFAC to investigate and quantify the onset response. Using this method, it is possible to show quantitatively that the onset response has two phases with distinct characteristics. Eliminating the onset response is likely to require addressing each phase independently. It was also possible to show that HFAC establishes a complete block of nerve activity in 50-100 ms.

摘要

由于高频交流电（HFAC）起始时会产生大量神经活动，其在周围神经中阻断神经传导的临床应用受到限制。必须对这种“起始反应”进行表征，以确定是否有可能消除它。在本研究中，使用HFAC的计数周期在体内动物模型中进行了初步实验，以研究和量化起始反应。使用这种方法，可以定量显示起始反应有两个具有不同特征的阶段。消除起始反应可能需要分别处理每个阶段。还可以表明，HFAC在50 - 100毫秒内可完全阻断神经活动。

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计数周期法量化高频周围神经阻滞中的起始反应。

Counted cycles method to quantify the onset response in high-frequency peripheral nerve block.

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