乌龟视网膜中无长突细胞和神经节细胞上的离心作用
Centrifugal actions on amacrine and ganglion cells in the retina of the turtle.
作者信息
Marchiafava P L
出版信息
J Physiol. 1976 Feb;255(1):137-55. doi: 10.1113/jphysiol.1976.sp011273.
Abstract
- An electrophysiological investigation of efferent synapses in the retina of the turtle was conducted by recording intracellularly from amacrine cells. These cells have been selected because in birds they have been shown to have direct anatomical connexions with centrifugal fibre terminals. 2. Amacrine cells could be easily distinguished from most other retinal cells, except ganglion cells, by their different photo-responses. Because both amacrine and ganglion cells may generate action potentials they were distinguished by their responses to optic nerve stimulation. 3. The response of ganglion cells to single shock stimulation of the optic nerve consists of an antidromic action potential followed by a late synaptic potential. 4. Cells which did not show antidromic responses but were electrically excitable, by passing direct current through the recording electrode, were considered to be amacrine cells. 5. Amacrine cells generate an e.p.s.p. in response to optic nerve stimulation. An analysis of the e.p.s.p. suggests that it may be due to a single afferent fibre terminating in the proximity of the cell soma. By analogy to the bird, it is concluded that the amacrine cells e.p.s.p.s result from the activation of centrifugal fibres.
摘要
- 通过对无长突细胞进行细胞内记录,对乌龟视网膜中的传出突触进行了电生理研究。选择这些细胞是因为在鸟类中,它们已被证明与离心纤维终末存在直接的解剖学联系。2. 除神经节细胞外,无长突细胞可通过其不同的光反应轻松与大多数其他视网膜细胞区分开来。由于无长突细胞和神经节细胞都可能产生动作电位,因此通过它们对视神经刺激的反应来区分。3. 神经节细胞对视神经单次电击刺激的反应包括一个逆向动作电位,随后是一个晚期突触电位。4. 那些未表现出逆向反应但通过将直流电通过记录电极可被电兴奋的细胞被认为是无长突细胞。5. 无长突细胞在视神经刺激时产生兴奋性突触后电位(e.p.s.p.)。对该兴奋性突触后电位的分析表明,它可能是由于一条传入纤维在细胞体附近终止所致。类比鸟类的情况,得出结论:无长突细胞的兴奋性突触后电位是由离心纤维的激活引起的。
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