乌龟视网膜中神经节细胞的自易化作用。
Self-facilitation of ganglion cells in the retina of the turtle.
作者信息
Marchiafava P L, Torre V
出版信息
J Physiol. 1977 Jun;268(2):335-51. doi: 10.1113/jphysiol.1977.sp011860.
Abstract
- Ganglion cells responses to illumination and to optic nerve stimulation were recorded intracellularly from the retina of the turtle. All ganglion cells were identified by their antidromic responses to optic nerve stimulation.2. When solitary spikes are produced following antidromic, orthodromic or intracellular stimulation, about 20% of the recorded ganglion cells show an additional depolarization along the falling phase of the action potential (post-spike depolarization, PSD).3. The PSD following the antidromic action potential disappears upon collision with a direct spike or when the antidromic spike is prevented from invading the cell soma.4. By pairing two optic nerve stimuli the PSD is depressed with brief interstimulus intervals, but gradually recovers to the control amplitude 600-800 msec after the conditioning shock.5. The PSD is tentatively interpreted as an e.p.s.p. transmitted by ganglion cell collaterals originating at the level of the soma dendritic complex of the recorded cell.6. The interspike interval histogram of ganglion cells showing PSD is characterized by a peak at about 10 msec, as opposed to a peak between 12 and 100 msec observed in cells without PSD. It is suggested that the occurrence of PSD facilitate the onset of additional action potentials at brief interspikes intervals, thus potentiating ganglion cell discharges.
摘要
从海龟视网膜细胞内记录神经节细胞对光照和视神经刺激的反应。所有神经节细胞均通过其对视神经刺激的逆向反应来识别。
当在逆向、顺向或细胞内刺激后产生单个峰电位时,约20%的记录神经节细胞在动作电位的下降相表现出额外的去极化(峰后去极化,PSD)。
逆向动作电位后的PSD在与直接峰电位碰撞时消失,或者当逆向峰电位被阻止侵入细胞体时消失。
通过配对两个视神经刺激,PSD在短的刺激间隔时受到抑制,但在条件刺激后600 - 800毫秒逐渐恢复到对照幅度。
PSD初步解释为起源于记录细胞体树突复合体水平的神经节细胞侧支传递的兴奋性突触后电位。
显示PSD的神经节细胞的峰电位间隔直方图的特征是在约10毫秒处有一个峰值,而在没有PSD的细胞中观察到的峰值在12至100毫秒之间。有人提出,PSD的出现有助于在短的峰电位间隔时产生额外的动作电位,从而增强神经节细胞的放电。
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