Recent evidence suggests that mesoscopic neural oscillations measured via intracranial
electroencephalography exhibit spatial representations, which were previously only …

Grid cells and theta oscillations are fundamental components of the brain's navigation
system. Grid cells provide animals [1, 2] and humans [3, 4] with a spatial map of the …

The entorhinal cortex contains a network of grid cells that play a fundamental part in the
brain's spatial system, supporting tasks such as path integration and spatial memory. In …

Grid cells and theta oscillations are fundamental constituents of the brain's navigation
system and have been described in the entorhinal cortex (EC). Recent fMRI studies reveal …

Path integration is a navigation strategy that requires animals to integrate self-movements
during exploration to determine their position in space. The medial entorhinal cortex (MEC) …

Grid cells are one of the core building blocks of spatial navigation [1]. Single-cell recordings
of grid cells in the rodent entorhinal cortex revealed hexagonal coding of the local …

We previously demonstrated that the phase of oscillations modulates neural activity
representing categorical information using human intracranial recordings and high …

Knowing where we are, where we have been, and where we are going is critical to many
behaviors, including navigation and memory. One potential neuronal mechanism underlying …

When a rat moves, grid cells in its entorhinal cortex become active in multiple regions of the
external world that form a hexagonal lattice. As the animal traverses one such “firing field,” …

The spatially periodic activity of grid cells in the entorhinal cortex (EC) of the rodent, primate,
and human provides a coordinate system that, together with the hippocampus, informs an …