乌龟视网膜中水平细胞反应的空间特性。
Spatial properties of horizontal cell responses in the turtle retina.
作者信息
Lamb T D
出版信息
J Physiol. 1976 Dec;263(2):239-55. doi: 10.1113/jphysiol.1976.sp011630.
Abstract
- Intracellular recordings were made from horizontal cells in the retina of the turtle Pseudemys scripta elegans. Spatial properties of the responses were determined using brief flashes of monochromatic light. 2. For a light stimulus in the form of a long narrow slit the peak response decayed approximately exponentially with displacement from the centred position. 3. With variation in the area of a centred circular patch, the peak response increased in a graded manner with stimulus area but was not proportional to area. 4. The model of electrical coupling in the horizontal cell layer proposed by Naka & Rushton (1976) was applied to the results. For the case of dim illumination a simplification is applicable, and the voltage distribution for circular and slit-shaped patches of light can be expressed in terms of two unknowns: the voltage resulting from diffuse illumination and a characteristic 'length constant'. 5. The measured variation of response amplitude was well described by the theory. Measured length constants were distributed from less than 100 mum to greater than 1 mm, and in a given cell the values determined by the slit displacement method and the area variation method were in reasonable agreement. 6. It is concluded that with dim illumination the model provides an accurate description of the voltage spread in the cells. Deviations were found to occur at higher intensities and possible reasons are discussed. 7. The implications of the model on the measurement of resistance changes during illunination are discussed.
摘要
- 对锦龟(Pseudemys scripta elegans)视网膜中的水平细胞进行了细胞内记录。使用单色光的短暂闪光来确定反应的空间特性。2. 对于长而窄的狭缝形式的光刺激,峰值反应随着从中心位置的位移大致呈指数衰减。3. 随着中心圆形光斑面积的变化,峰值反应随刺激面积呈分级增加,但与面积不成正比。4. 中田和拉什顿(1976)提出的水平细胞层电耦合模型被应用于这些结果。对于弱光照明的情况,可以进行简化,圆形和狭缝形光斑块的电压分布可以用两个未知数来表示:漫射照明产生的电压和一个特征“长度常数”。5. 该理论很好地描述了测量到的反应幅度变化。测量到的长度常数分布范围从小于100微米到大于1毫米,并且在给定的细胞中,通过狭缝位移法和面积变化法确定的值相当一致。6. 得出的结论是,在弱光照明下,该模型准确描述了细胞中的电压传播。发现在较高强度下会出现偏差,并讨论了可能的原因。7. 讨论了该模型对光照期间电阻变化测量的影响。
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本文引用的文献
1
Effects of extrinsic electric current on the cyprinid fish EIRG (S-potential).外部电流对鲤科鱼类EIRG(S电位)的影响。
Jpn J Physiol. 1960 Apr 29;10:132-41. doi: 10.2170/jjphysiol.10.132.
2
Electric responses from the isolated retinas of fishes.鱼类离体视网膜的电反应。
Am J Ophthalmol. 1958 Sep;46(3 Part 2):26-40; discussion 40-6. doi: 10.1016/0002-9394(58)90053-9.
3
The generation and spread of S-potentials in fish (Cyprinidae).鱼类(鲤科)中S电位的产生与传播。
J Physiol. 1967 Sep;192(2):437-61. doi: 10.1113/jphysiol.1967.sp008308.
4
Electrical connexions between horizontal cells in the dogfish retina.角鲨视网膜中水平细胞之间的电连接。
J Physiol. 1971 Feb;213(1):95-105. doi: 10.1113/jphysiol.1971.sp009370.
5
[Passive electric properties of a flat cell model].
Biofizika. 1969 Mar-Apr;14(2):328-35.
6
Detection and resolution of visual stimuli by turtle photoreceptors.乌龟光感受器对视觉刺激的检测与分辨
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7
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