Euclidean distances as dissimilarity between all possible pairs of two visual stimuli were calculated by using the visual responses of the 68 pulvinar neurons. Then, the mds program (proxscal procedure, spss statistical package, version 16) positioned the visual stimuli in the two-dimensional space with the distances between the stimuli representing the original relationships (i.e. Euclidean distances in the present study; Shepard, 1962; Kruskal, 1964). Recordings were made from a total of 401 neurons
from the pulvinar nuclei of two monkeys. One-hundred and sixty-five neurons responded to visual stimuli and, of these, 68 neurons were tested selleck chemicals with all of the visual stimuli. The mean spontaneous firing rate was 12.15 ± 1.14 spikes/s (n = 68; mean ± SEM) and the mean firing rate during stimulus presentation (500 ms) was 24.67 ± 2.50 spikes/s (n = 68). The pulvinar visually responsive neurons showed robust responses especially during the first 100 ms after stimulus onset. Figure 4 shows such an example
of a pulvinar neuron that responded to various visual stimuli. The activity of the neuron increased sharply in response to the onset of the stimuli, then decreased rapidly, and then gradually RO4929097 solubility dmso increased again. This pattern of changes in neuronal activity formed two response phases – an early rapid response phase and a late gradual response phase. This neuron responded strongly to the face-like patterns (Fig. 4G), especially in the late phase. Figure 5A shows response magnitudes Dapagliflozin of the neuron shown in Fig. 4 during stimulus presentation (500 ms) of all of the visual stimuli. There were significant differences in response magnitudes to the various visual stimuli (F48,563 = 5.821, P < 0.001; differential neuron). All of the 68 neurons tested displayed differential responses to the various stimuli (one-way anova, P < 0.05). Furthermore, the neuron responded differentially to gaze direction in M2 and W1 (dotted lines; Tukey test, P < 0.05). In addition, there were
significant differences in mean response magnitudes to the five stimulus categories (F4,607 = 31.36, P < 0.001). Subsequent post hoc tests indicated that mean response magnitude to the face-like patterns was significantly greater than those to the stimuli in the other stimulus categories (Tukey tests, P < 0.001). The overall mean responses indicated that the pulvinar neurons responded stronger to the face-related stimuli (facial photos, cartoon faces, eye-like patterns and face-like patterns) than the non-face stimuli (simple geometric patterns). Figure 5B illustrates the mean response magnitudes of the 68 visually responsive neurons during stimulus presentation (500 ms) to the face-related and non-face stimuli. The mean response magnitude of the 68 visually responsive neurons to the face-related stimuli was significantly larger than that to the non-face stimuli (F1,3330 = 5.76, P < 0.05).