- The hippocampus is a part of the brain that plays an important role in memory
- How hippocampal time cells are generated to remember the sequence of items in our memory has been found by researchers at the University of Warwick
- Now that we understand how the order events are stored in the brain, we now have a better foundation for exploring brain dysfunctions relating to memory, including the changes in memory in healthy ageing, Alzheimer’s disease, and the memory for sad events in depression.
For centuries understanding how the order of events is stored in memory has been a mystery. However, researchers from the Department of Computer Science at the University of Warwick have worked out how the order of events in memory could be stored and later recalled in the hippocampal memory system in the brain.
The new research published in the journal ‘Cell Reports’ titled ‘The Generation of Time in the Hippocampal Memory System’ builds on the discovery by Nobel prize winners May-Britt and Edvard Moser that an input region to the hippocampus – the lateral entorhinal cortex (LEC) – has time ramping cells that slowly change their rates of activity over hundreds of seconds; and on the discovery that hippocampal time cells fire at separate times in a sequence.
In the new research a theory and model was developed of how entorhinal time ramping cells produce hippocampal time cells which can be associated with places and people to help remember the sequence in which the people and places occurred during the remembered episode.
The theory demonstrates how we can remember what happened to us during the day in the correct order, and how we can provide an eye witness memory for a series of events.
The researchers show how the transformation of the code of the memory between the two brain areas – the LEC and the hippocampus – is achieved by a well-known type of neural network present in the brain, a competitive network.
The competitive network learns to allocate hippocampal neurons to respond to different combinations of the firing of the time ramping cells, and thus a temporal sequence can be formed.
The theory also accounts for the slow activity changes in time ramping cells by adaptation mechanisms, and shows how spontaneous memory recall can occur with the correct order of items in the memory.
Understanding the brain’s memory and related mechanisms is helping not only to understand disorders of memory, but also is providing new approaches to understanding and treating mental disorders including depression and schizophrenia.
Further details of Prof. Rolls’ approach to a better understanding of depression building on these foundations is provided in his new book, ‘The Brain, Emotion and Depression’ published in 2018. It shows for example how sad memories dominate in depression, and provides suggestions for treatment.
Professor Edmund Rolls from the Department of Computer Science at the University of Warwick comments:
“This is an exciting time for research on the brain: we are starting to understand the underlying brain mechanisms for many types of behaviour including memory and emotion, and this has great potential for better treating brain disorders.”