Department of Pharmacology and Toxicology, University of Utah, Salt Lake City, Utah, U.S.A; Anticonvulsant Drug Development Program, University of Utah, Salt Lake City, Utah, U.S.A; Interdepartmental Neuroscience Program, University of Utah, Salt Lake City, Utah, U.S.A.
Epilepsia. 2014 Feb;55(2):214-23. doi: 10.1111/epi.12524. Epub 2014 Jan 21.
Cognitive comorbidities are increasingly recognized as an equal (or even more disabling) aspect of epilepsy. In addition, the actions of some antiseizure drugs (ASDs) can impact learning and memory. Accordingly, the National Institute of Neurological Disorders and Stroke (NINDS) epilepsy research benchmarks call for the implementation of standardized protocols for screening ASDs for their amelioration or exacerbation of cognitive comorbidities. Long-term potentiation (LTP) is a widely used model for investigating synaptic plasticity and its relationship to learning and memory. Although the effects of some ASDs on LTP have been examined, none of these studies employed physiologically relevant induction stimuli such as theta-burst stimulation (TBS). To systematically evaluate the effects of multiple ASDs in the same preparation using physiologically relevant stimulation protocols, we examined the effects of a broad panel of existing ASDs on TBS-induced LTP in area CA1 of in vitro brain slices, prepared in either normal or sucrose-based artificial cerebrospinal fluid (ACSF), from C57BL/6 mice.
Coronal brain slices containing the dorsal hippocampus were made using either standard or sucrose-based ACSF. Recordings were obtained from four slices at a time using the Scientifica Slicemaster high throughput recording system. Slices exposed to ASDs were paired with slices from the opposite hemisphere that served as controls. Field excitatory postsynaptic potentials (fEPSPs) were recorded, and all ASDs were applied to slices by bath perfusion for 20 min prior to the induction stimulus. LTP was induced by TBS or by high-frequency stimulation (HFS). The following ASDs were examined: 100 μM phenobarbital (PB), 80 μM phenytoin (PHT), 50 μM carbamazepine (CBZ), 600 μM valproate (VPA), 60 μM topiramate (TPM), 60 μM lamotrigine (LTG), 100 μM levetiracetam (LEV), 10 μM ezogabine (EZG), and 30 μM tiagabine (TGB).
Among voltage-gated sodium channel inhibitors, CBZ significantly attenuated TBS-induced LTP, PHT attenuated both TBS-induced LTP and post-tetanic potentiation (PTP), and LTG failed to affect LTP but did attenuate PTP. ASDs that modulate γ-aminobutyric acid (GABA)ergic synaptic transmission, such as PB and TGB, significantly attenuated LTP in brain slices prepared in sucrose-based ACSF but not standard ACSF. Third generation ASDs, such as LEV and TPM, did not affect LTP in ACSF- or sucrose-prepared brain slices. Although EZG failed to affect LTP, it did significantly attenuate PTP under both slicing conditions. VPA failed to affect LTP in area CA1, both in C57BL/6 mice and Sprague-Dawley rats, using TBS or HFS. However, VPA did attenuate TBS-induced LTP in the dentate gyrus (DG).
The results of experiments describe herein provide a comprehensive summary of the effects of many commonly used ASDs on short- and long-term synaptic plasticity while, for the first time, using physiologically relevant LTP induction protocols and slice preparations from mice. Furthermore, methodologic variables, such as brain slice preparation protocols, were explored. These results provide comparative knowledge of ASD effects on synaptic plasticity in the mouse hippocampus and may ultimately contribute to an understanding of the differences in the cognitive side effect profiles of ASDs and the prediction of cognitive dysfunction associated with novel investigational ASDs.
认知共病越来越被认为是癫痫的一个同等(甚至更具致残性)方面。此外,一些抗癫痫药物(ASD)的作用会影响学习和记忆。因此,美国国立神经病学和中风研究所(NINDS)的癫痫研究基准要求实施标准化方案,筛选 ASD 对认知共病的改善或恶化作用。长时程增强(LTP)是一种广泛用于研究突触可塑性及其与学习和记忆关系的模型。尽管已经研究了一些 ASD 对 LTP 的影响,但这些研究都没有使用生理相关的诱导刺激,如 theta 爆发刺激(TBS)。为了使用生理相关的刺激方案在同一制剂中系统地评估多种 ASD 的作用,我们检查了广泛的现有 ASD 对 CA1 区脑片 TBS 诱导的 LTP 的影响,该脑片来自 C57BL/6 小鼠,使用标准或基于蔗糖的人工脑脊液(ACSF)制备。
使用标准或基于蔗糖的 ACSF 制作含有背侧海马的冠状脑片。使用 Scientifica Slicemaster 高通量记录系统同时从四个切片中获取记录。暴露于 ASD 的切片与对侧半球的对照切片配对。记录场兴奋性突触后电位(fEPSP),并通过灌流将所有 ASD 应用于切片 20 分钟,然后进行诱导刺激。通过 TBS 或高频刺激(HFS)诱导 LTP。检查了以下 ASD:100μM 苯巴比妥(PB)、80μM 苯妥英(PHT)、50μM 卡马西平(CBZ)、600μM 丙戊酸钠(VPA)、60μM 托吡酯(TPM)、60μM 拉莫三嗪(LTG)、100μM 左乙拉西坦(LEV)、10μM 依佐加滨(EZG)和 30μM 噻加宾(TGB)。
在电压门控钠通道抑制剂中,CBZ 显著减弱了 TBS 诱导的 LTP,PHT 减弱了 TBS 诱导的 LTP 和强直后增强(PTP),而 LTG 未能影响 LTP,但减弱了 PTP。调节γ-氨基丁酸(GABA)能突触传递的 ASD,如 PB 和 TGB,显著减弱了在基于蔗糖的 ACSF 制备的脑片中的 LTP,但在标准 ACSF 中没有。第三代 ASD,如 LEV 和 TPM,在 ACSF 或蔗糖制备的脑片中均未影响 LTP。尽管 EZG 未能影响 LTP,但它在两种切片条件下均显著减弱了 PTP。VPA 未能影响 C57BL/6 小鼠和 Sprague-Dawley 大鼠 CA1 区的 LTP,无论是使用 TBS 还是 HFS。然而,VPA 确实减弱了 TBS 诱导的 DG 中的 LTP。
本文所述实验的结果提供了对许多常用 ASD 对短期和长期突触可塑性的影响的综合总结,同时首次使用生理相关的 LTP 诱导方案和来自小鼠的切片制备。此外,还探讨了方法学变量,如脑片制备方案。这些结果提供了关于 ASD 对小鼠海马体突触可塑性影响的比较知识,并可能最终有助于理解 ASD 的认知副作用谱的差异以及与新的研究性 ASD 相关的认知功能障碍的预测。
