Fanselow E E, Reid A P, Nicolelis M A
Departments of Neurobiology and Biomedical Engineering, Duke University Medical Center, Durham, North Carolina 27710, USA.
J Neurosci. 2000 Nov 1;20(21):8160-8. doi: 10.1523/JNEUROSCI.20-21-08160.2000.
Stimulation of the vagus nerve has become an effective method for desynchronizing the highly coherent neural activity typically associated with epileptic seizures. This technique has been used in several animal models of seizures as well as in humans suffering from epilepsy. However, application of this technique has been limited to unilateral stimulation of the vagus nerve, typically delivered according to a fixed duty cycle, independently of whether ongoing seizure activity is present. Here, we report that stimulation of another cranial nerve, the trigeminal nerve, can also cause cortical and thalamic desynchronization, resulting in a reduction of seizure activity in awake rats. Furthermore, we demonstrate that providing this stimulation only when seizure activity begins results in more effective and safer seizure reduction per second of stimulation than with previous methods. Seizure activity induced by intraperitoneal injection of pentylenetetrazole was recorded from microwire electrodes in the thalamus and cortex of awake rats while the infraorbital branch of the trigeminal nerve was stimulated via a chronically implanted nerve cuff electrode. Continuous unilateral stimulation of the trigeminal nerve reduced electrographic seizure activity by up to 78%, and bilateral trigeminal stimulation was even more effective. Using a device that automatically detects seizure activity in real time on the basis of multichannel field potential signals, we demonstrated that seizure-triggered stimulation was more effective than the stimulation protocol involving a fixed duty cycle, in terms of the percent seizure reduction per second of stimulation. In contrast to vagus nerve stimulation studies, no substantial cardiovascular side effects were observed by unilateral or bilateral stimulation of the trigeminal nerve. These findings suggest that trigeminal nerve stimulation is safe in awake rats and should be evaluated as a therapy for human seizures. Furthermore, the results demonstrate that seizure-triggered trigeminal nerve stimulation is technically feasible and could be further developed, in conjunction with real-time seizure-predicting paradigms, to prevent seizures and reduce exposure to nerve stimulation.
刺激迷走神经已成为一种使通常与癫痫发作相关的高度相干神经活动去同步化的有效方法。该技术已在多种癫痫动物模型以及癫痫患者中得到应用。然而,这项技术的应用仅限于单侧刺激迷走神经,通常按照固定的占空比进行,而与是否存在正在进行的癫痫活动无关。在此,我们报告刺激另一对颅神经——三叉神经,也可导致皮质和丘脑去同步化,从而使清醒大鼠的癫痫活动减少。此外,我们证明仅在癫痫活动开始时提供这种刺激,相较于先前的方法,每秒钟刺激能更有效且更安全地减少癫痫发作。在清醒大鼠的丘脑和皮质中,通过微丝电极记录腹腔注射戊四氮诱发的癫痫活动,同时经长期植入的神经袖套电极刺激三叉神经的眶下支。持续单侧刺激三叉神经可使脑电图癫痫活动减少高达78%,双侧三叉神经刺激甚至更有效。使用一种基于多通道场电位信号实时自动检测癫痫活动的装置,我们证明就每秒钟刺激减少癫痫发作的百分比而言,癫痫发作触发刺激比涉及固定占空比的刺激方案更有效。与迷走神经刺激研究不同,单侧或双侧刺激三叉神经均未观察到明显的心血管副作用。这些发现表明,三叉神经刺激在清醒大鼠中是安全的,应作为一种治疗人类癫痫的方法进行评估。此外,结果表明癫痫发作触发的三叉神经刺激在技术上是可行的,并且可以结合实时癫痫预测范式进一步开发,以预防癫痫发作并减少神经刺激暴露。