Galletti C, Battaglini P P, Aicardi G
Cattedra di Fisiologia generale della Facolta' di Farmacia, Universita' di Bologna, Italy.
Exp Brain Res. 1988;69(2):279-88. doi: 10.1007/BF00247573.
Extracellular recordings were made in area V2 of behaving macaque monkeys. Neurons were classified into three groups: non-oriented cells, oriented cells with antagonistic areas and oriented cells without antagonistic areas in their receptive field. All neurons were tested with standard visual stimulations in order to assess whether they gave different responses to the movement of a stimulus and to the movement of its retinal image alone, when the stimulus was motionless and the animal voluntarily moved its eyes. To do this, neuronal responses obtained when a moving stimulus swept a stationary receptive field (during steady fixation) and when a moving receptive field swept a stationary stimulus (during tracking eye movements), were compared. The receptive field stimulation at retinal level was physically the same in both cases, but only in the first was there actual movement of the visual stimulus. Control trials, where the monkeys performed tracking eye movements without any intentional receptive field stimulation, were also carried out. Out of a total of 263 neurons isolated in the central 10 deg representation of area V2, 101 were fully studied with the visual stimulation described above. Most of these (83/101; 82%) gave about the same response to the two situations. About 14% (14/101) gave a good response to stimulus movements during steady fixation and a very weak one to retinal image displacements of stationary stimuli during visual tracking. We have called neurons of this type "real-motion cells" (cf. Galletti et al. 1984). None of the non-oriented cells was a real-motion one, while about an equal percentage of real-motion cells was found among the oriented cells with and without antagonistic areas. Finally, we found only 4 neurons which showed behaviour opposite to that of real-motion cells, i.e. they showed a better response to displacement of the retinal image of stationary stimuli than to actual movement of stimuli. We suggest that real-motion cells might contribute to correctly evaluating movement in the visual field in spite of eye movements and that they might allow recognition of the movement of an object even if it moves across a non-patterned visual background. Present data on area V2, together with similar results observed in area V1 (Galletti et al. 1984; Battaglini et al. 1986), support the view that these two cortical areas analyse the movement in a parallel fashion along with many other characteristics of the visual stimulus.
在行为猕猴的V2区进行了细胞外记录。神经元被分为三组:非定向细胞、感受野中有拮抗区的定向细胞和感受野中无拮抗区的定向细胞。所有神经元都接受了标准视觉刺激测试,以评估当刺激静止而动物自主移动眼睛时,它们对刺激的移动和单独视网膜图像的移动是否给出不同反应。为此,比较了移动刺激扫过静止感受野时(在稳定注视期间)和移动感受野扫过静止刺激时(在跟踪眼动期间)获得的神经元反应。两种情况下视网膜水平的感受野刺激在物理上是相同的,但只有第一种情况存在视觉刺激的实际移动。还进行了对照试验,即猴子在没有任何有意感受野刺激的情况下进行跟踪眼动。在V2区中央10度表征中分离出的总共263个神经元中,101个用上述视觉刺激进行了全面研究。其中大多数(83/101;82%)对两种情况给出大致相同的反应。约14%(14/101)在稳定注视期间对刺激移动给出良好反应,而在视觉跟踪期间对静止刺激的视网膜图像位移给出非常微弱的反应。我们将这种类型的神经元称为“真实运动细胞”(参见Galletti等人,1984年)。非定向细胞中没有一个是真实运动细胞,而在有拮抗区和无拮抗区的定向细胞中发现的真实运动细胞比例大致相等。最后,我们只发现4个神经元表现出与真实运动细胞相反的行为,即它们对静止刺激的视网膜图像位移的反应比对刺激的实际移动的反应更好。我们认为,真实运动细胞可能有助于在存在眼动的情况下正确评估视野中的运动,并且它们可能允许识别物体的运动,即使它在无图案的视觉背景上移动。目前关于V2区的数据,以及在V1区观察到类似结果(Galletti等人,1984年;Battaglini等人,1986年),支持了这两个皮层区域与视觉刺激的许多其他特征一起以并行方式分析运动的观点。
