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对骶背根神经节传入神经进行微刺激可诱发膀胱反射活动。

Microstimulation of afferents in the sacral dorsal root ganglia can evoke reflex bladder activity.

作者信息

Bruns Tim M, Weber Douglas J, Gaunt Robert A

机构信息

Department of Physical Medicine and Rehabilitation, University of Pittsburgh, Pittsburgh, Pennysylvania.

出版信息

Neurourol Urodyn. 2015 Jan;34(1):65-71. doi: 10.1002/nau.22514. Epub 2014 Jan 24.

Abstract

AIMS

Pudendal afferent fibers can be excited using electrical stimulation to evoke reflex bladder activity. While this approach shows promise for restoring bladder function, stimulation of desired pathways, and integration of afferent signals for sensory feedback remains challenging. At sacral dorsal root ganglia (DRG), the convergence of pelvic and pudendal afferent fibers provides a unique location for access to lower urinary tract neurons. Our goal in this study was to demonstrate the potential of microstimulation in sacral DRG for evoking reflex bladder responses.

METHODS

Penetrating microelectrode arrays were inserted in the left S1 and S2 DRG of six anesthetized adult male cats. While the bladder volume was held at a level below the leak volume, single and multiple channel stimulation was performed using various stimulation patterns.

RESULTS

Reflex bladder excitation was observed in five cats, for stimulation in either S1 or S2 DRG at 1 Hz and 30-33 Hz with a pulse amplitude of 10-50 µA. Bladder relaxation was observed during a few trials. Adjacent electrodes frequently elicited very different responses.

CONCLUSIONS

These results demonstrate the potential of low-current microstimulation to recruit reflexive bladder responses. An approach such as this could be integrated with DRG recordings of bladder afferents to provide a closed-loop bladder neuroprosthesis.

摘要

目的

使用电刺激可激发阴部传入纤维,以诱发膀胱反射活动。虽然这种方法在恢复膀胱功能方面显示出前景,但刺激所需通路以及整合传入信号以实现感觉反馈仍具有挑战性。在骶背根神经节(DRG),盆部和阴部传入纤维的汇聚为接触下尿路神经元提供了一个独特的位置。本研究的目的是证明在骶DRG中进行微刺激诱发膀胱反射反应的潜力。

方法

将穿透式微电极阵列插入六只麻醉成年雄性猫的左侧S1和S2 DRG。在膀胱容积保持在低于漏尿容积的水平时,使用各种刺激模式进行单通道和多通道刺激。

结果

在五只猫中观察到膀胱反射性兴奋,在S1或S2 DRG以1Hz和30 - 33Hz、脉冲幅度为10 - 50µA进行刺激时出现。在少数试验中观察到膀胱松弛。相邻电极经常引发非常不同的反应。

结论

这些结果证明了低电流微刺激诱发反射性膀胱反应的潜力。这样的方法可以与膀胱传入神经的DRG记录相结合,以提供一种闭环膀胱神经假体。

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