Incubation of rat hippocampal slices in solutions containing low Ca2+ and increased Mg2+ rapidly blocked synaptic responses and increased spontaneous firing of all the principal neurones. More remarkably, a rhythmic and synchronous bursting discharge developed, which was restricted to the CA1 population of pyramidal neurones. These 'field bursts' or 'spreading excitation' were rapidly abolished by restoring the Ca2+ to 2 mM, by increasing the Mg2+ to 6 mM or by decreasing K+ from 6 to 3 mM. The CA1 pyramidal cells depolarized after the change to the low-Ca2+ solution by about 10-20 mV. Individual field bursts were associated with a further depolarization of 10-12 mV surmounted by a burst of action potentials at about 20/s. This transient depolarization shift, recorded extracellularly as a negative field, could be attributed to the increase of [K+]o during the bursts, reaching 9-10 mM as measured by ion-sensitive electrodes. The bursts were followed by a hyperpolarization, seen extracellularly as a small soma-positive field, which was attributed to an electrogenic pump and/or a Ca2+-activated K+ conductance. Stimulation of the tightly packed pyramidal cell axons in the alveus elicited a train of population spikes, instead of the single spike normally seen, and could trigger a full field burst. Recordings of the alvear tract volley suggested that the repeated spikes arose within the pyramidal cells. Multiple recordings from CA1 revealed that field bursts usually, but by no means always, started near the caudal (subicular) end of the area. They spread through the cell layer at 0.04-0.12 m/s. The most rapid propagation was seen when the bursts had an abrupt onset; slower propagation (1-10 mm/s) occurred when the bursts started gradually, which generally was the case near the sites of burst initiation and termination. Usually the action potentials within each burst were synchronized into population spikes which spread across CA1 at 0.04-0.15 m/s. The site of initiation and the extent of the spread of these population spikes varied during each burst, as did their amplitude. The degree of spike synchronization was enhanced by various treatments expected to increase neuronal excitability. Measurements of transmembrane potential during the burst confirmed the role in the generation of population spikes of ephaptic or field interactions between the pyramidal cells. It is proposed that the increased firing of all neurones is due to the block of tonic inhibition, depression of after-hyperpolarization and to increased membrane excitability.(ABSTRACT TRUNCATED AT 400 WORDS)
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机译:在含有低Ca2 +和增加的Mg2 +的溶液中孵育大鼠海马切片会迅速阻止突触反应,并增加所有主要神经元的自发放电。更为显着的是,出现了节律性和同步性爆发放电,这种放电仅限于锥体神经元的CA1群体。通过将Ca2 +恢复到2 mM,将Mg2 +增加到6 mM或将K +从6减少到3 mM,这些“场爆发”或“扩散激发”被迅速消除。在更改为低Ca2 +溶液约10-20 mV后,CA1锥体细胞去极化。单个场脉冲与以约20 / s的动作电位脉冲克服的10-12 mV的进一步去极化有关。这种瞬态去极化位移,在细胞外被记录为负电场,可以归因于爆发期间[K +] o的增加,如离子敏感电极所测,达到9-10 mM。爆发后发生超极化,在细胞外被视为一个小的躯体阳性区域,这归因于电泵和/或Ca2 +激活的K +电导。刺激肺泡中紧密堆积的锥体细胞轴突会引起一系列的种群尖峰,而不是通常看到的单个尖峰,并且可能触发全场爆发。烟道齐射的记录表明,在锥体细胞内出现了重复的尖峰。来自CA1的多次记录表明,通常在该区域的尾部(特定)末端附近开始爆发,但并非总是如此。它们以0.04-0.12 m / s的速度扩散穿过细胞层。当爆发突然爆发时,可以看到最快的传播。逐渐开始爆发时,会出现较慢的传播速度(1-10 mm / s),这通常是在爆发起始和终止位置附近的情况。通常,每个爆发内的动作电位都与群体峰值同步,并以0.04-0.15 m / s的速度跨CA1传播。在每次爆发期间,这些种群峰值的始发部位和扩散程度以及振幅都不同。通过预期增加神经元兴奋性的各种治疗,刺突同步程度得以提高。爆破过程中跨膜电位的测量证实了在锥体细胞之间的突触或田间相互作用的种群尖峰的产生中的作用。提出所有神经元的放电增加是由于抑制了补品,抑制了超极化后的抑制以及增加了膜的兴奋性。(摘要截短了400字)
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