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通过自适应逐步增加高频(10kHz)双相刺激强度进行阴部神经阻滞

Pudendal Nerve Block by Adaptively Stepwise Increasing the Intensity of High-Frequency (10 kHz) Biphasic Stimulation.

作者信息

Jian Jianan, Wang Jicheng, Shen Bing, Shen Zhijun, Goosby Khari, Scolieri Joseph, Beckel Jonathan, de Groat William C, Tai Changfeng

机构信息

Department of Urology, University of Pittsburgh, Pittsburgh, PA, USA.

Department of Pharmacology and Chemical Biology, University of Pittsburgh, Pittsburgh, PA, USA.

出版信息

Neuromodulation. 2025 Feb;28(2):249-255. doi: 10.1016/j.neurom.2023.03.015. Epub 2023 Apr 29.

DOI:10.1016/j.neurom.2023.03.015
PMID:37125972
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10613126/
Abstract

OBJECTIVE

The purpose of this study is to determine whether adaptively stepwise increasing the intensity of a high-frequency (10 kHz) biphasic stimulation (HFBS) can produce nerve conduction block without generating a large initial response.

MATERIALS AND METHODS

In anesthetized cats, three cuff electrodes were implanted on the left pudendal nerve for stimulation or block. The urethral pressure increase induced by pudendal nerve stimulation was used to measure the pudendal nerve block induced by HFBS.

RESULTS

HFBS applied suddenly with a large step increase in intensity induced a large (86 ± 16 cmHO) urethral pressure increase before it blocked pudendal nerve conduction. However, HFBS applied by adaptively stepwise increasing the intensity every 10 to 60 seconds over a long period (33-301 minutes; average 108 ± 35 minutes) with many small intensity increases (0.005-0.1 mA) induced no response or low-amplitude high-frequency urethral pressure changes before it blocked pudendal nerve conduction. The minimal HFBS intensities required by the two different methods to block pudendal nerve conduction are similar.

CONCLUSION

This study is important for better understanding the possible mechanisms underlying the HFBS-induced nerve block and provides the possibility of developing a new nerve block method for clinical applications in which an initial large response is a concern.

摘要

目的

本研究旨在确定高频(10kHz)双相刺激(HFBS)强度的适应性逐步增加是否能在不产生大的初始反应的情况下导致神经传导阻滞。

材料与方法

在麻醉猫身上,将三个袖带电极植入左侧阴部神经用于刺激或阻滞。阴部神经刺激引起的尿道压力升高用于测量HFBS诱导的阴部神经阻滞。

结果

强度大幅突然增加的HFBS在阻滞阴部神经传导之前会引起较大的(86±16cmH₂O)尿道压力升高。然而,在较长时间(33 - 301分钟;平均108±35分钟)内每10至60秒适应性逐步增加强度且有许多小强度增加(0.005 - 0.1mA)的HFBS,在阻滞阴部神经传导之前未引起反应或仅引起低幅度高频尿道压力变化。两种不同方法阻滞阴部神经传导所需的最小HFBS强度相似。

结论

本研究对于更好地理解HFBS诱导神经阻滞的潜在机制具有重要意义,并为开发一种新的神经阻滞方法提供了可能性,该方法适用于临床应用中关注初始大反应的情况。

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