Department of Psychology, McGill University, Montreal, Quebec, Canada.
J Neurophysiol. 2012 Sep;108(5):1228-43. doi: 10.1152/jn.00840.2011. Epub 2012 Jun 6.
From our daily experience, it is very clear that relative motion cues can contribute to correctly identifying object boundaries and perceiving depth. Motion-defined contours are not only generated by the motion of objects in a scene but also by the movement of an observer's head and body (motion parallax). However, the neural mechanism involved in detecting these contours is still unknown. To explore this mechanism, we extracellularly recorded visual responses of area 18 neurons in anesthetized and paralyzed cats. The goal of this study was to determine if motion-defined contours could be detected by neurons that have been previously shown to detect luminance-, texture-, and contrast-defined contours cue invariantly. Motion-defined contour stimuli were generated by modulating the velocity of high spatial frequency sinusoidal luminance gratings (carrier gratings) by a moving squarewave envelope. The carrier gratings were outside the luminance passband of a neuron, such that presence of the carrier alone within the receptive field did not elicit a response. Most neurons that responded to contrast-defined contours also responded to motion-defined contours. The orientation and direction selectivity of these neurons for motion-defined contours was similar to that of luminance gratings. A given neuron also exhibited similar selectivity for the spatial frequency of the carrier gratings of contrast- and motion-defined contours. These results suggest that different second-order contours are detected in a form-cue invariant manner, through a common neural mechanism in area 18.
从我们的日常经验可以清楚地看出,相对运动线索有助于正确识别物体边界和感知深度。运动定义的轮廓不仅由场景中物体的运动产生,还由观察者头部和身体的运动(运动视差)产生。然而,用于检测这些轮廓的神经机制仍然未知。为了探索这种机制,我们在麻醉和麻痹的猫中进行了 18 区神经元的细胞外记录。本研究的目的是确定先前已经证明能够检测亮度、纹理和对比度定义轮廓线索不变的神经元是否可以检测到运动定义的轮廓。运动定义的轮廓刺激是通过调制高空间频率正弦亮度光栅(载波光栅)的速度来产生的,其由移动的方波包络调制。载波光栅在神经元的亮度通带之外,因此在感受野内仅存在载波本身不会引起反应。对对比度定义轮廓有反应的大多数神经元也对运动定义的轮廓有反应。这些神经元对运动定义的轮廓的方向和方向选择性与亮度光栅相似。给定的神经元对对比度和运动定义的轮廓的载波光栅的空间频率也表现出相似的选择性。这些结果表明,不同的二阶轮廓通过 18 区中的共同神经机制以形式线索不变的方式被检测到。
