The brain’s RAM: Rats, like humans, have a “working memory”

Thousands of times a day, the brain stores sensory information for very short periods of time in a working memory, to be able to use it later. A research study carried out with the collaboration of SISSA has shown, for the first time, that this function also exists in the brain of rodents, a finding that sheds light on the evolutionary origins of this cognitive mechanism.

In computers it’s called “RAM”, but the mechanism is conceptually similar to what scientists call a “working memory” in the brain of humans and primates: when we interact with the environment our senses gather information that a temporary memory system keeps fresh and readily accessible for a few minutes, so that the body can carry out operations (for example, an action). For the first time, a research team coordinated by Mathew Diamond of the International School for Advanced Studies (SISSA) in Trieste has shown that this memory system also exists in simpler mammals like rodents.

Working memory has been studied in detail in humans and primates, but little was known about its existence in other animals. “Knowing that a working memory also exists in the brain of evolutionarily simpler organisms helps us to understand the origins of this important cognitive mechanism”, explains Diamond. “Comparative psychology studies have historically helped scientists not only to trace the evolutionary roots of human brain functions but also to gain deeper insight into human cognitive processes themselves”.

The type of sensory memory studied by Diamond and co-workers in rats is tactile memory. The performance of rodents in tasks assessing recognition of vibratory stimuli was compared with that of humans performing similar tasks (rats used their whiskers and humans their fingertips). “Rats exhibited similar behaviour patterns to humans, demonstrating that these animals use a tactile working memory that enables them to recognise and interact with environmental stimuli”. The research paper has been published in The Proceedings of the National Academy of Sciences (PNAS).

More in detail…

“Working memory is an extraordinary cognitive mechanism”, comments Diamond. “It’s like a container where the brain stores little bits of very recent experience, to be able to assess the best course of action. Without this temporary memory, experience would slip away without any chance of being used”.

“Working memory can hold only a limited amount of information for a fairly short period of time. These limits are the result of a cost-benefit balance: the brain’s computational capacity is fixed and decisions as to what action to take often need to be quick and effective as the same time. Our working memory’s capacity is therefore the best we can achieve in terms of accuracy and speed with our brain”.

“The brain regions responsible for working memory have not yet been identified in rats. Some believe that rats don’t have the brain centres known as “prefrontal cortex” which are involved in this function in primates”, continues Diamond. ”Our surprise was to discover that rodents realize memory in a manner similar to humans. Now we are continuing our studies to understand how these mechanisms work in detail”.

Rats! Humans and rodents face their errors

What happens when the brain recognizes an error? A new study shows that the brains of humans and rats adapt in a similar way to errors by using low-frequency brainwaves in the medial frontal cortex to synchronize neurons in the motor cortex. The finding could be important in studies of “adaptive control” like obsessive compulsive disorder, ADHD, and Parkinson’s.

People and rats may think alike when they’ve made a mistake and are trying to adjust their thinking.

That’s the conclusion of a study published online Oct. 20 in Nature Neuroscience that tracked specific similarities in how human and rodent subjects adapted to errors as they performed a simple time estimation task. When members of either species made a mistake in the trials, electrode recordings showed that they employed low-frequency brainwaves in the medial frontal cortex (MFC) of the brain to synchronize neurons in their motor cortex. That action correlated with subsequent performance improvements on the task.

“These findings suggest that neuronal activity in the MFC encodes information that is involved in monitoring performance and could influence the control of response adjustments by the motor cortex,” wrote the authors, who performed the research at Brown University and Yale University.

The importance of the findings extends beyond a basic understanding of cognition, because they suggest that rat models could be a useful analog for humans in studies of how such “adaptive control” neural mechanics are compromised in psychiatric diseases.

“With this rat model of adaptive control, we are now able to examine whether novel drugs or other treatment procedures boost the integrity of this system,” said James Cavanagh, co-lead author of the paper who was at Brown when the research was done and has since become assistant professor of psychology at the University of New Mexico. “This may have clear translational potential for treating psychiatric diseases such as obsessive compulsive disorder, depression, attention deficit hyperactivity disorder, Parkinson’s disease and schizophrenia.”

To conduct the study, the researchers measured external brainwaves of human and rodent subjects after both erroneous and accurate performance on the time estimation task. They also measured the activity of individual neurons in the MFC and motor cortex of the rats in both post-error and post-correct circumstances.

The scientists also gave the rats a drug that blocked activity of the MFC. What they saw in those rats compared to rats who didn’t get the drug, was that the low-frequency waves did not occur in the motor cortex, neurons there did not fire coherently and the rats did not alter their subsequent behavior on the task.

Although the researchers were able to study the cognitive mechanisms in the rats in more detail than in humans, the direct parallels they saw in the neural mechanics of adaptive control were significant.

“Low-frequency oscillations facilitate synchronization among brain networks for representing and exerting adaptive control, including top-down regulation of behavior in the mammalian brain,” they wrote.

Australian scientists map mouse brains in greatest detail yet

Hopes for a cure for many brain diseases may rest on the humble mouse, now that scientists can map the rodents’ brains more thoroughly than ever before.

Researchers at The University of Queensland’s Centre for Advanced Imaging (CAI) and Curtin University have created the most detailed atlas of the mouse brain, a development that is helping in the fight against brain disease.

This new tool will allow researchers to map what parts of the brain are affected in mouse models of brain disease – such as brain cancer, Parkinson’s disease and Alzheimers disease, which affect nearly 1 in 6 of the world’s population.

Lead author, Dr Jeremy Ullmann said that the new brain atlas provided a fundamental tool for the neuroscience community.

“The mouse is now the most widely used animal model for neuroscience research and magnetic resonance imaging (MRI) is fundamental to investigating changes in the brain,” Dr Ullman said.

“Our atlas is already much in demand internationally because it allows researchers to use MRI to automatically map brain structures.”

The atlas was created in the laboratory of Professor David Reutens, CAI Director.

“In making these world-first maps, we had the advantage of using the most powerful MRI scanners in the Southern Hemisphere, backed up by leaders in digital image analysis, resulting in remarkably clear images of the brain,” Professor Reutens said.

The project’s lead neuroanatomist, Professor Charles Watson from Curtin University, believes that the study will open the door to accurate analysis of gene targeting in the mouse brain.

“The invention of gene targeting in the mouse has made this species the centrepiece of studies on models of human brain disease. MRI allows researchers to follow changes in the brain over time in the same animals,” Professor Watson said.

The atlas was recently described in an article published in the journal NeuroImage.