光遗传刺激背侧纹状体可双向控制癫痫发作

Safwan K Hyder, Willian Lazarini-Lopes, Jonathan Toib, Gabrielle Williams, Alex Sukharev, Patrick A Forcelli
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引用次数: 0

摘要

75 年前首次观察到癫痫发作时纹状体(尾状体/普门)和其他基底节核团的参与。基底节输出核,尤其是黑质网状旁,在大量实验模型中具有公认的抗癫痫作用。然而,对纹状体控制癫痫发作的研究却不足。为了填补这一空白,我们使用光遗传学方法激活和失活了斯普拉格-道利大鼠背侧纹状体中的神经元,这些大鼠分别接受了失神性癫痫的γ-丁内酯(GBL)模型、颞叶癫痫的杏仁核点燃模型以及皮质类药物诱发的癫痫状态(SE)。所有测试均以受试者为单位进行。动物在两种不同的光频(5 Hz 和 100 Hz)下接受测试。在所有模型中,对背侧纹状体神经元的开环(连续光传递)光遗传激活都能强有力地抑制癫痫发作。另一方面,背侧纹状体神经元的光遗传沉默增加了失神发作的表达并促进了SE的发作,但对点燃的肢体发作没有影响。在 GBL 模型中,我们还验证了闭环策略(响应癫痫发作检测的光传递)是否足以诱导抗癫痫效应。在表达 ChR2 的动物中,按需光照会缩短 SWD 的持续时间,而在表达 ArchT 的动物中,同样的方法会延长 SWD 的持续时间。这些结果表明,纹状体持续和按需神经调节具有以前未曾认识到的抗失神效应。这些发现共同证明了背侧纹状体在多种癫痫发作模型(包括局灶性癫痫发作起始和全身性癫痫发作)中控制癫痫发作产生和传播的强大双向作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optogenetic stimulation of dorsal striatum bidirectionally controls seizures
Engagement of the striatum (caudate/putamen) and other basal ganglia nuclei during seizures was first observed over 75 years ago. Basal ganglia output nuclei, and the substantia nigra pars reticulata, in particular, have well-established anti-seizure effects across a large array of experimental models. However, striatal control fo seizures is understudied. To address this gap, we used optogenetic approaches to activate and inactivate neurons in the dorsal striatum of Sprague-Dawley rats submitted to the gamma-butyrolactone (GBL) model of absence epilepsy, amygdala kindling model of temporal lobe epilepsy, and pilocarpine-induced Status Epilepticus (SE). All tests were performed on a within-subject basis. Animals were tested in two different light frequencies (5 Hz and 100 Hz). Open-loop (continuous light delivery) optogenetic activation of the dorsal striatal neurons robustly suppressed seizures in all models. On the other hand, optogenetic silencing of the dorsal striatal neurons increased absence seizure expression and facilitated SE onset but had no effect on kindled limbic seizures. In the GBL model, we also verified if the closed-loop strategy (light delivery in response to seizure detection) would be enough to induce antiseizure effects. On-demand light delivery in ChR2-expressing animals reduced SWD duration, while the same approach in ArchT-expressing animals increased SWD duration. These results demonstrated previously unrecognized anti-absence effects associated with striatal continuous and on-demand neuromodulation. Together, these findings document a robust, bidirectional role of the dorsal striatum in the control of seizure generation and propagation in a variety of seizure models, including focal seizure onset and generalized seizures.
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