Abstract
As we look around a scene, we perceive it as continuous and stable even though each saccadic eye movement changes the visual input to the retinas. How the brain achieves this perceptual stabilization is unknown, but a major hypothesis is that it relies on presaccadic remapping, a process in which neurons shift their visual sensitivity to a new location in the scene just before each saccade. This hypothesis is difficult to test in vivo because complete, selective inactivation of remapping is currently intractable. We tested it in silico with a hierarchical, sheet-based neural network model of the visual and oculomotor system. The model generated saccadic commands to move a video camera abruptly. Visual input from the camera and internal copies of the saccadic movement commands, or corollary discharge, converged at a map-level simulation of the frontal eye field (FEF), a primate brain area known to receive such inputs. FEF output was combined with eye position signals to yield a suitable coordinate frame for guiding arm movements of a robot. Our operational definition of perceptual stability was “useful stability,” quantified as continuously accurate pointing to a visual object despite camera saccades. During training, the emergence of useful stability was correlated tightly with the emergence of presaccadic remapping in the FEF. Remapping depended on corollary discharge but its timing was synchronized to the updating of eye position. When coupled to predictive eye position signals, remapping served to stabilize the target representation for continuously accurate pointing. Graded inactivations of pathways in the model replicated, and helped to interpret, previous in vivo experiments. The results support the hypothesis that visual stability requires presaccadic remapping, provide explanations for the function and timing of remapping, and offer testable hypotheses for in vivo studies. We conclude that remapping allows for seamless coordinate frame transformations and quick actions despite visual afferent lags. With visual remapping in place for behavior, it may be exploited for perceptual continuity.
Highlights
Frequent eye movements known as saccades allow us look around a visual scene rapidly, but at the cost of disrupting the continuity of visual information
The visual input to the model was provided by a video camera, and the oculomotor output was provided by the superior colliculus (SC) along two pathways: a “motor” branch that controlled the camera to move it with simulated saccades, and a “corollary discharge” branch that provided the model with copies of the saccadic commands
Using the network without CD, every time the robot made a saccade (Figure 2, gray), the locus of neurons responding to the stimulus updated only after the visual latency of 70 ms, when new visual information arrived at the frontal eye field (FEF) (Figure 2, green)
Summary
Frequent eye movements known as saccades allow us look around a visual scene rapidly, but at the cost of disrupting the continuity of visual information. Neurons that remap use predictive oculomotor information to shift their locus of visual analysis just before each saccade (Walker et al, 1995; Umeno and Goldberg, 1997; Nakamura and Colby, 2002). The effect of remapping a visual response parallel to the saccade is to sample the location of visual space, the “future field,” that will be occupied by the classical receptive field after the saccade. This provides the opportunity for distinguishing changes in visual input that arise from self-motion from those due to external image movement, and some neurons in FEF make this distinction (Crapse and Sommer, 2012). We have a long way to go in understanding subjective visual continuity across saccades, the prevailing hypothesis is that it is attributable to presaccadic visual remapping (Melcher and Colby, 2008)
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