刺激空间频率依赖性对比检测的神经相关物。

Neural correlates of stimulus spatial frequency-dependent contrast detection.

机构信息

College of Life Sciences, Anhui Normal University, Wuhu, 241000, China.

出版信息

Exp Brain Res. 2013 Mar;225(3):377-85. doi: 10.1007/s00221-012-3378-z. Epub 2013 Jan 12.

DOI:10.1007/s00221-012-3378-z

PMID:23314692

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4959422/

Abstract

UNLABELLED

Psychophysical studies on human and non-human vertebrate species have shown that visual contrast sensitivity function (CSF) peaks at a certain stimulus spatial frequency and declines in both lower and higher spatial frequencies. The underlying neural substrate and mechanisms remain in debate. Here, we investigated the role of primary visual cortex (V1: area 17) in spatial frequency-dependent contrast detection in cats. Perceptual CSFs of three cats were measured using a two-alternative forced-choice task. The responses of V1 neurons to their optimal visual stimuli in a range of luminance contrast levels (from 0 to 1.0) were recorded subsequently using in vivo extracellular single-unit recording techniques. The contrast sensitivity of each neuron was determined. The neuronal CSF for each cat was constructed from the mean contrast sensitivity of neurons with different preferred stimulus spatial frequencies.

RESULT

(1) The perceptual and neuronal CSFs of each of the three cats exhibited a similar shape with peak amplitude near 0.4 cpd. (2) The neuronal CSF of each cat was highly correlated with its perceptual CSF. (3) V1 neurons with different preferred stimulus spatial frequencies had different contrast gains.

CONCLUSION

(1) Contrast detection of visual stimuli with different spatial frequencies may likely involve population coding of V1 neurons with different preferred stimulus spatial frequencies. (2) Difference in contrast gain may underlie the observed contrast sensitivity variation of V1 neurons with different preferred stimulus spatial frequencies, possibly from either evolution or postnatal visual experiences.

摘要

未加标签

对人类和非人类脊椎动物物种的心理物理学研究表明，视觉对比敏感度函数 (CSF) 在特定的刺激空间频率处达到峰值，并在较低和较高的空间频率处下降。其潜在的神经基质和机制仍存在争议。在这里，我们研究了初级视觉皮层 (V1：17 区) 在猫的空间频率依赖性对比检测中的作用。使用二选一强制选择任务测量了三只猫的感知 CSF。随后使用活体细胞外单细胞记录技术记录了 V1 神经元对其最佳视觉刺激在一系列亮度对比水平（从 0 到 1.0）的反应。确定了每个神经元的对比敏感度。从具有不同首选刺激空间频率的神经元的平均对比敏感度构建了每只猫的神经元 CSF。

结果

(1) 三只猫的感知和神经元 CSF 都具有相似的形状，峰值幅度在 0.4 cpd 附近。(2) 每只猫的神经元 CSF 与感知 CSF 高度相关。(3) 具有不同首选刺激空间频率的 V1 神经元具有不同的对比增益。

结论

(1) 对不同空间频率的视觉刺激的对比检测可能涉及具有不同首选刺激空间频率的 V1 神经元的群体编码。(2) 对比增益的差异可能是导致具有不同首选刺激空间频率的 V1 神经元的观察到的对比敏感度变化的原因，这可能来自于进化或出生后的视觉体验。

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