Role of Vestibular Signals in the Caudal Part of the Frontal Eye Fields in Pursuit Eye Movements in Three-Dimensional Space

doi:10.1196/annals.1325.026

For accurate visual information about objects of interest movingslowly in three-dimensional (3D) space, primates with binocularfields use both frontal smooth-pursuit (frontal-pursuit) andvergence eye movements (i.e., depth pursuit) to maintain theimages of the objects precisely on the foveae of left and righteyes. Moreover, during head or whole-body movement, both frontal-and depth-pursuit systems must interact with the vestibularsystem to minimize slip of the retinal mages that degrades imagequality considerably. The caudal part of the frontal eye fields(FEF) contains many frontal-pursuit neurons. Previous studieshave shown that a majority of pursuit neurons there dischargefor both frontal pursuit and vergence and carry pursuit-in-3Dsignals. To understand how vestibular inputs interact with pursuit-in-3Dsignals, three different experiments that examined the natureof vestibular signals in the caudal FEF are described in thisreview. A majority of caudal FEF pursuit neurons responded towhole-body rotation with preferred directions similar to frontal-pursuitdirections and carried frontal gaze (eye-in-space) velocitysignals. They were activated in association with adaptive pursuiteye movements induced by cross-axis pursuit-vestibular interactions.During fore/aft and right/left translation in complete darkness,they were also modulated with preferred directions of many neuronssimilar to pursuit-preferred directions. Previous studies showedthat caudal FEF pursuit neurons also receive visual signalsabout target motion. Taken together, these results suggest thatthe caudal FEF coordinates its various inputs to provide signalsfor accurate eye-movement-in-space commands.