Hwa G G, Avoli M, Oliver A, Villemure J G
Montreal Neurological Institute, Québec, Canada.
Exp Brain Res. 1991;83(2):329-39. doi: 10.1007/BF00231156.
Intracellular and extracellular recordings were made from human neocortical slices of the temporal lobe maintained in vitro. The slices were treated with bicuculline methiodide to reduce synaptic inhibition mediated by tha gamma-aminobutyric acid A (GABAA) receptor. Spontaneously occurring epileptiform activity was never observed in over 60 slices examined. All epileptiform discharges were elicited by single-shock stimuli delivered in the underlying white matter or within the cortical layers. Intracellularly, the stimulus-induced epileptiform discharge resembled the paroxysmal depolarization shift (PDS). This potential was observed in neurons located between 200 and 2200 microns from the pia. It was characterized by a 100-1800 ms long depolarization which triggered burst firing of action potentials, and was at times followed by an afterdischarge. Simultaneous intracellular and extracellular recordings showed that each PDS was reflected by the synchronous discharge of a neuronal aggregate. The voltage behaviour of the PDS and its preceding EPSP was analyzed in cells that were injected with the lidocaine derivative QX-314. The amplitudes of the PDS depolarizing envelope measured at its peak and during its falling phase both behaved as a monotonic function of the membrane potential by increasing in amplitude during hyperpolarization. In addition, the PDS peak amplitude showed a much greater rate of increase than the early EPSP peak amplitude, thus suggesting that the synaptic conductance underlying the PDS was much greater. Perfusion of the neocortical slices with the N-Methyl-D-aspartate (NMDA) receptor antagonist DL-2-amino-phosphonovaleric acid (APV) reduced both the duration and the amplitude of the paroxysmal field discharge in a dose related fashion. The effects of APV were reflected intracellularly by an attenuation of the PDS's late phase and a blockade of the afterdischarge. Similar findings were also obtained by using the NMDA receptor antagonist 3-((+-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid. These data indicate that reduction or blockade of the GABAA receptor is sufficient to elicit epileptiform discharges in the human neocortex maintained in vitro. Mechanisms dependent upon the NMDA receptor contribute to this type of epileptiform response mainly by prolonging the stimulus-induced depolarizing potential and the associated burst of firing.
对体外培养的人类颞叶新皮质切片进行细胞内和细胞外记录。切片用甲硫酸荷包牡丹碱处理,以减少由γ-氨基丁酸A(GABAA)受体介导的突触抑制。在检查的60多个切片中从未观察到自发出现的癫痫样活动。所有癫痫样放电均由在深层白质或皮质层内施加的单次电击刺激诱发。在细胞内,刺激诱发的癫痫样放电类似于阵发性去极化偏移(PDS)。这种电位在距软脑膜200至2200微米之间的神经元中观察到。其特征是持续100 - 1800毫秒的去极化,引发动作电位的爆发性放电,有时随后伴有后放电。同时进行的细胞内和细胞外记录表明,每个PDS都由神经元聚集体的同步放电反映出来。在注射利多卡因衍生物QX - 314的细胞中分析了PDS及其之前的兴奋性突触后电位(EPSP)的电压行为。在PDS去极化包络的峰值及其下降阶段测量的幅度,在超极化期间幅度增加,均表现为膜电位的单调函数。此外,PDS峰值幅度的增加速率比早期EPSP峰值幅度大得多,因此表明PDS背后的突触电导要大得多。用N - 甲基 - D - 天冬氨酸(NMDA)受体拮抗剂DL - 2 - 氨基 - 磷酸戊酸(APV)灌注新皮质切片,以剂量相关方式降低了阵发性场放电的持续时间和幅度。APV的作用在细胞内表现为PDS后期的衰减和后放电的阻断。使用NMDA受体拮抗剂3 - ((±) - 2 - 羧基哌嗪 - 4 - 基) - 丙基 - 1 - 膦酸也获得了类似的结果。这些数据表明,减少或阻断GABAA受体足以在体外培养的人类新皮质中引发癫痫样放电。依赖于NMDA受体的机制主要通过延长刺激诱发的去极化电位和相关的爆发性放电,对这种类型的癫痫样反应起作用。
