TY - JOUR T1 - Encoding of Smooth Pursuit Direction and Eye Position by Neurons of Area MSTd of Macaque Monkey JF - The Journal of Neuroscience JO - J. Neurosci. SP - 3847 LP - 3860 DO - 10.1523/JNEUROSCI.17-10-03847.1997 VL - 17 IS - 10 AU - Salvatore Squatrito AU - Maria Grazia Maioli Y1 - 1997/05/15 UR - http://www.jneurosci.org/content/17/10/3847.abstract N2 - The spike activity of neurons was recorded from the dorsal bank of the superior temporal sulcus (area MSTd) of alert behaving macaque monkeys performing visual fixation or target tracking tasks, with the aim of studying the tuning features of these neurons with both the direction of slow eye movement and the position of gaze. One hundred thirty-two neurons were tested for several fixation points and tracking directions. Many of them (43%) tuned to the direction of pursuit, regardless of the angle of gaze. Some (18%) showed a tonic discharge modulated by the static position of the eyes without pursuit direction specificity. A substantial number of cells (22%) were characterized by a discharge rate tuned to pursuit direction but influenced also by angle of gaze. Tuning curves for eye movement direction presented an average bandwidth of 130° and turned out to be continuously overlapping, suggesting a sort of vector coding of smooth pursuit direction. Gaze fields of eye position (EP) neurons were mostly ramp-like, with center of ramps shifted away from the straight ahead, implying a form of scalar coding of gaze eccentricity. The different categories of cells were intermingled and close to each other, suggesting possible reciprocal interactions within the same cortical area. These results show that EP and pursuit direction are signaled mainly by separate neuronal elements in area MSTd. Moreover, some cells can integrate both signals. Taking into account the visual responses of MSTd neurons to large, textured, moving fields, it is suggested that this area could be the site of interaction between visuo-oculomotor signals related to visual motion detection, slow eye movement direction, and EP. This signal interaction may be important for integrative functions such as analysis of external or self-induced visual motion, cortical control of pursuit eye movements, and eye/head coordination. ER -