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猫视网膜神经节细胞的非线性空间总和与对比度增益控制。

Nonlinear spatial summation and the contrast gain control of cat retinal ganglion cells.

作者信息

Shapley R M, Victor J D

出版信息

J Physiol. 1979 May;290(2):141-61. doi: 10.1113/jphysiol.1979.sp012765.

DOI:10.1113/jphysiol.1979.sp012765
PMID:469742
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1278829/
Abstract
  1. We studied how responses to visual stimuli at spatially separated locations were combined by cat retinal ganglion cells. 2. The temporal signal which modulated the stimuli was a sum of sinusoids. Fourier analysis of the ganglion cell impulse train yielded first order responses at the modulation frequencies, and second order responses at sums and differences of the input frequencies. 3. Spatial stimuli were spots in the centre and periphery of the cell's receptive field. Four conditions of stimulation were used: centre alone, periphery alone, centre and periphery in phase, centre and periphery out of phase. 4. The effective first order response of the centre was defined as the response due to centre stimulation in the presence of periphery stimulation, but independent of the relative phases of the two regions. Likewise, the effective first order response of the periphery was defined as the response due to periphery in the presence of centre stimulation, but independent of the relative phases of the two regions. These effective responses may be calculated by addition and subtraction of the measured responses to the combined stimuli. 5. There was a consistent difference between the first order frequency kernal of the effective centre and the first order kernel of the centre alone. The amplitudes of the effective centre responses were diminished at low frequencies of modulation compared to the isolated centre responses. Also, the phase of the effective centre's response to high frequencies was advanced. Such non-linear interaction occurred in all ganglion cells, X or Y, but the effects were larger in Y cells. 6. In addition to spatially uniform stimuli in the periphery, spatial grating patterns were also used. These peripheral gratings affected the first order kernal of the centre even though the peripheral gratings produced no first order responses by themselves. 7. The temporal properties of the non-linear interaction of centre and periphery were probed by modulation in the periphery with single sinusoids. The most effective temporal frequencies for producing non-linear summation were: (a) 4-15 Hz when all the visual stimuli were spatially uniform, (b) 2-8 Hz when spatial grating patterns were used in the periphery. 8. The characteristics of non-linear spatial summation observed in these experiments are explained by the properties of the contrast gain control mechanism which we have previously postulated.
摘要
  1. 我们研究了猫视网膜神经节细胞如何整合对空间分离位置的视觉刺激的反应。2. 调制刺激的时间信号是正弦波的总和。对神经节细胞冲动序列进行傅里叶分析,在调制频率处产生一阶反应,在输入频率的和与差处产生二阶反应。3. 空间刺激是细胞感受野中心和周边的光点。使用了四种刺激条件:单独中心刺激、单独周边刺激、中心和周边同相、中心和周边异相。4. 中心的有效一阶反应定义为在周边刺激存在下由中心刺激引起的反应,但与两个区域的相对相位无关。同样,周边的有效一阶反应定义为在中心刺激存在下由周边引起的反应,但与两个区域的相对相位无关。这些有效反应可以通过对组合刺激的测量反应进行加减计算得出。5. 有效中心的一阶频率核与单独中心的一阶核之间存在一致差异。与孤立的中心反应相比,有效中心反应的幅度在低频调制时减小。此外,有效中心对高频的反应相位提前。这种非线性相互作用发生在所有神经节细胞中,X 或 Y 细胞,但在 Y 细胞中的影响更大。6. 除了周边的空间均匀刺激外,还使用了空间光栅图案。这些周边光栅影响了中心的一阶核,即使周边光栅本身不产生一阶反应。7. 通过在外周用单个正弦波进行调制来探究中心和周边非线性相互作用的时间特性。产生非线性总和的最有效时间频率为:(a) 当所有视觉刺激在空间上均匀时为 4 - 15 Hz,(b) 当在外周使用空间光栅图案时为 2 - 8 Hz。8. 这些实验中观察到的非线性空间总和的特征可以用我们之前假设的对比度增益控制机制的特性来解释。
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0c83/1278829/594d4b983bd8/jphysiol00873-0165-a.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0c83/1278829/594d4b983bd8/jphysiol00873-0165-a.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0c83/1278829/594d4b983bd8/jphysiol00873-0165-a.jpg

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