Brain has number of modules to provide sense of location

London: Your brain has at least four and as many as 10 different senses of location, operating independently of each other, according to a new study.

Researchers from the Kavli Institute for Systems Neuroscience, at the Norwegian University of Science and Technology found that rather than just a single sense of location, the brain has a number of "modules" dedicated to self-location.

Each module contains its own internal Global Positioning System (GPS)-like mapping system that keeps track of movement, and has other characteristics that also distinguishes one from another.

"We have at least four senses of location," said Edvard Moser, director of the Kavli Institute.

"Each has its own scale for representing the external environment, ranging from very fine to very coarse. The different modules react differently to changes in the environment. Some may scale the brain`s inner map to the surroundings, others do not. And they operate independently of each other in several ways," Moser said in a statement.

This is also the first time that researchers have been able to show that a part of the brain that does not directly respond to sensory input, called the association cortex, is organised into modules.

The research was conducted using rats. A rat`s brain is the size of a grape, while the area that keeps track of the sense of location and memory is comparable in size to a small grape seed. This tiny area holds millions of nerve cells.

A research team of six people worked for more than four years to acquire extensive electrophysiological measurements in this seed-sized region of the brain.

New measurement techniques and a technical breakthrough made it possible for Hanne Stensola and her colleagues to measure the activity in as many as 186 grid cells of the same rat brain.

A grid cell is a specialised cell named for its characteristic of creating hexagonal grids in the brain`s mental map of its surroundings.
"We knew that the `grid maps` in this area of the brain had resolutions covering different scales, but we did not know how independent the scales were of each other," Stensola said.

"We then discovered that the maps were organised in four to five modules with different scales, and that each of these modules reacted slightly differently to changes in their environment," Stensola said.

"This independence can be used by the brain to create new combinations - many combinations - which is a very useful tool for memory formation," Stensola added.