Highlights•Brief review of what's known–and unknown-about spatial and feature remapping
across saccades.•Focus: what is the timing of remapping of spatial attention, and what is the …

About 25 years ago, the discovery of receptive field (RF) remapping in the parietal cortex of
nonhuman primates revealed that visual RFs, widely assumed to have a fixed retinotopic …

Coordination of goal-directed behavior depends on the brain's ability to recover the
locations of relevant objects in the world. In humans, the visual system encodes the spatial …

Each saccade shifts the projections of the visual scene on the retina. It has been proposed
that the receptive fields of neurons in oculomotor areas are predictively remapped to …

Visual perception has been suggested to operate on temporal 'chunks' of sensory input,
rather than on a continuous stream of visual information. Saccadic eye movements impose a …

Our visual system is fundamentally retinotopic. When viewing a stable scene, each eye
movement shifts object features and locations on the retina. Thus, sensory representations …

Storing information from incoming stimuli in working memory (WM) is essential for decision-
making. The prefrontal cortex (PFC) plays a key role to support this process. Previous …

While making saccadic eye-movements to scan a visual scene, humans and monkeys are
able to keep track of relevant visual stimuli by maintaining spatial attention on them. This …

Across saccades, humans can integrate the low-resolution presaccadic information of an
upcoming saccade target with the high-resolution postsaccadic information. There is …

Natural orienting of gaze often results in a retinal image that is rotated relative to space due
to ocular torsion. However, we perceive neither this rotation nor a moving world despite …