Núñez A, García-Austt E, Buño W
Brain Res. 1987 Jul 28;416(2):289-300. doi: 10.1016/0006-8993(87)90909-7.
The hippocampal EEG and the transmembrane potential of CA1-CA3 hippocampal pyramids were recorded in curarized and urethanized rats. Pyramids were identified by antidromic driving and intracellular staining with Lucifer yellow. During theta-rhythm most pyramids showed 10-20 mV sustained depolarizations and potential oscillations either consisting of 5-10 mV smooth sine-like waves or slow spikes of up to 60 mV. Fast Na+ and slow, probably Ca2+-mediated, spikes were triggered by depolarizing pulses or spontaneously. Depolarizations greater than 15 mV triggered rhythmic slow spikes at theta-frequency, but if less than 15 mV, slow spikes were irregular and at lower rates. With depolarizations of less than 10 mV, no slow spikes were triggered. Sine-like intracellular theta-wave amplitudes increased with hyper- and decreased with depolarizing pulses, showing the behavior of rhythmic EPSPs. Periodic fast spike bursts were theta-correlated. Cells with intracellular theta could either fire periodic fast spike bursts or at random, but always at a preferred phase of the theta-wave. Slow spikes were generated above a potential threshold by a slow depolarization and driven by periodic EPSPs. Intracellular theta is the reflection of EPSPs and of slow spikes; the oscillatory phenomena are not exclusively generated, as previously hypothesized, by network properties which may, however, contribute as tuning and modulatory elements. The determining events in intracellular theta-generation are the intrinsic biophysical characteristics of the pyramidal neuron membrane.
在箭毒化和氨基甲酸乙酯麻醉的大鼠中记录海马脑电图和CA1 - CA3海马锥体神经元的跨膜电位。通过逆向驱动和用荧光黄进行细胞内染色来识别锥体神经元。在θ节律期间,大多数锥体神经元表现出10 - 20 mV的持续去极化和电位振荡,振荡电位要么由5 - 10 mV的平滑正弦样波组成,要么由高达60 mV的慢波峰组成。快速的Na⁺峰和缓慢的、可能由Ca²⁺介导的峰可由去极化脉冲触发或自发产生。大于15 mV的去极化会触发θ频率的节律性慢波峰,但如果小于15 mV,慢波峰则不规则且频率较低。当去极化小于10 mV时,不会触发慢波峰。细胞内正弦样θ波的振幅随超极化而增加,随去极化脉冲而减小,表现出节律性兴奋性突触后电位(EPSP)的行为。周期性的快速波峰爆发与θ波相关。具有细胞内θ波的细胞要么会产生周期性的快速波峰爆发,要么随机发放,但总是在θ波的一个偏好相位。慢波峰由缓慢的去极化在一个电位阈值以上产生,并由周期性的EPSP驱动。细胞内θ波是EPSP和慢波峰的反映;振荡现象并非如先前假设的那样完全由网络特性产生,不过网络特性可能作为调节和调制因素发挥作用。细胞内θ波产生的决定性事件是锥体神经元膜的内在生物物理特性。
