That favourite childhood memory of yours -- you know, the one that still seems like just yesterday, the one that you can still smell and taste -- may actually be the result of a select few neurons firing deep within your brain.
According to a recent MIT study, Strong memory fragments known as engrams may actually be the result of a small number of neurons residing in the hippocampus, the brain's memory centre. The team employed a technique known as optogenetics -- one that electrically stimulates genetically-modified neurons that are designed to light up when active -- to identify in mice the neurons responsible for long term memories. "We demonstrate that behaviour based on high-level cognition, such as the expression of a specific memory, can be generated in a mammal by highly specific physical activation of a specific small subpopulation of brain cells, in this case by light," says Susumu Tonegawa, a researcher at MIT.
The MIT team tested its hypothesis by first identifying the subset of brain cells within the Hippocampus that activated only when a lab mouse was learning a new maze route then combined the memory-making genes with one that produced a light-activated protein. This way, neurons responsible for new memory formation would literally light up whenever the cells were active.
The team then exposed a group of mice to a new maze environment with certain areas deemed "off limits" and enforced with a mild electrical shock. The mice quickly learned to solve the maze without venturing into the off limits areas while activating a certain subset of hippocampus neurons.
When the mice were dropped into a new maze with different electrified areas, every time they made a misstep, the same neurons that fired when the mouse was shocked in the previous maze, did so again in the new one. Not only that, in the new maze, the mouse entered into a defensive crouch faster and more readily than in the first. This shows that the mouse not only remembered the pain from the previous maze, it also learned from the experience and changed its behaviour because of it. Basically, the mouse remembered how much the shock sucked due to these neurons firing and therefore reacted faster.
"Showing that the reactivation of those nerve cells that were active during learning can reproduce the learned behavior is surely a milestone." Charles Stevens, a professor in the Molecular Neurobiology Laboratory at the Salk Institute, told R&D Magazine. The ability to know which specific bits of our brains activate when used could be applied to a variety of neurodegenerative disorder studies such as Alzheimer's by identifying which specific regions of the brain aren't working as they should. [MIT via R&D Mag - Image: Sebastian Kaulitzki / Shutterstock]