Neuron information processing In 2005, it was discovered that entorhinal cortex contains a
neural map of the spatial environment in rats. In 2014, John O'Keefe, May-Britt Moser and Edvard Moser received the
Nobel Prize in Physiology or Medicine, partly because of this discovery. In rodents, neurons in the lateral entorhinal cortex exhibit little spatial selectivity, whereas neurons of the medial entorhinal cortex (MEC), exhibit multiple "place fields" that are arranged in a hexagonal pattern, and are, therefore, called "
grid cells". These fields and spacing between fields increase from the dorso-lateral MEA to the ventro-medial MEA. The same group of researchers has found speed cells in the medial entorhinal cortex of rats. The speed of movement is translated from proprioceptive information and is represented as firing rates in these cells. The cells are known to fire in correlation to future speed of the rodent. Recently, a general theory has been proposed to elucidate the function of the
reelin positive cells in the layer II of the entorhinal cortex. According to this concept, these cells would be generally organized into 1-dimensional ring attractors, and in the
medial (in humans:
posteromedial) portion, would function as
grid cells (anatomically: stellate cells) while in
lateral (in humans:
anterolateral) portion, where they appear as fan cells, would enable the encoding of new episodic memories. This concept is underscored by the fact that fan cells of the entorhinal cortex are indispensable for the formation of episodic-like memories in rodents.
Single-unit recording of neurons in humans playing
video games find path cells in the EC, the activity of which indicates whether a person is taking a clockwise or counterclockwise path. Such EC "direction" path cells show this directional activity irrespective of the location of where a person experiences themselves, which contrasts them to place cells in the hippocampus, which are activated by specific locations. EC neurons process general information such as directional activity in the environment, which contrasts to that of the hippocampal neurons, which usually encode information about specific places. This suggests that EC encodes general properties about current contexts that are then used by hippocampus to create unique representations from combinations of these properties. whereas the lateral entorhinal cortex (LEC) mainly supports the processing of time. due to asymmetric theta oscillations. The underlying cause of these phase shifts and their waveform changes is unknown. Individual variation in the volume of EC is linked to taste perception. People with a larger EC in the left hemisphere found
quinine, the source of bitterness in
tonic water, less bitter. ==Clinical significance==