Nerve cells in our brains work together in harmony to store and retrieve short-term memory
Ottawa Hospital Research Institute News Mar 21, 2017
The research turns on its head decades of studies assuming that single neurons independently encode information in our working memories.
ÂThese findings suggest that even neurons we previously thought were Âuseless because they didnÂt individually encode information have a purpose when working in concert with other neurons, said researcher Julio Martinez–Trujillo, based at the Robarts Research Institute and the Brain and Mind Institute at Western University.
ÂKnowing they work together helps us better understand the circuits in the brain that can either improve or hamper executive function. And that in turn may have implications for how we work though brain–health issues where short–term memory is a problem, including Alzheimer disease, schizophrenia, autism, depression and attention deficit disorder.Â
Working memory is the ability to learn, retain and retrieve bits of information we all need in the short term: items on a grocery list or driving directions, for example. Working memory deteriorates faster in people with dementia or other disorders of the brain and mind.
In the past, researchers have believed this executive function was the job of single neurons acting independently from one another  the brainÂs version of a crowd of people in a large room all singing different songs in different rhythms and different keys. An outsider trying to decipher any tune in all that white noise would have an extraordinarily difficult task.
This research, however, suggests many in the neuron throng are singing from the same songbook, in essence creating chords to strengthen the collective voice of memory. With neural prosthetic technology  microchips that can Âlisten to many neurons at the same time  researchers are able to find correlations between the activity of many nerve cells. ÂUsing that same choir analogy, you can start perceiving some sounds that have a rhythm, a tune and chords that are related to each other: in sum, short–term memories, said Martinez–Trujillo, who is also an associate professor at WesternÂs Schulich School of Medicine & Dentistry.
And while the ramifications of this discovery are still being explored, Âthis gives us good material to work with as we move forward in brain research. It provides us with the necessary knowledge to find ways to manipulate brain circuits and improve short term memory in affected individuals, Martinez–Trujillo said.
ÂThe microchip technology also allows us to extract signals from the brain in order to reverse–engineer brain circuitry and decode the information that is in the subjectÂs mind, said Adam Sachs, neurosurgeon and associate scientist at The Ottawa Hospital and assistant professor at the University of Ottawa Brain and Mind Research Institute. ÂIn the near future, we could use this information to allow cognitive control of neural prosthetics in patients with ALS or severe cervical spinal cord injury.Â
The research was published in the Proceedings of the National Academy of Sciences journal. The research team members were Martinez–Trujillo; Sachs; Matthew Leavitt, a PhD student at the department of physiology at McGill University, Montreal; and Florian Pieper of the department of neuro– and pathophysiology at University Medical Centre Hamburg–Eppendorf in Germany.
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ÂThese findings suggest that even neurons we previously thought were Âuseless because they didnÂt individually encode information have a purpose when working in concert with other neurons, said researcher Julio Martinez–Trujillo, based at the Robarts Research Institute and the Brain and Mind Institute at Western University.
ÂKnowing they work together helps us better understand the circuits in the brain that can either improve or hamper executive function. And that in turn may have implications for how we work though brain–health issues where short–term memory is a problem, including Alzheimer disease, schizophrenia, autism, depression and attention deficit disorder.Â
Working memory is the ability to learn, retain and retrieve bits of information we all need in the short term: items on a grocery list or driving directions, for example. Working memory deteriorates faster in people with dementia or other disorders of the brain and mind.
In the past, researchers have believed this executive function was the job of single neurons acting independently from one another  the brainÂs version of a crowd of people in a large room all singing different songs in different rhythms and different keys. An outsider trying to decipher any tune in all that white noise would have an extraordinarily difficult task.
This research, however, suggests many in the neuron throng are singing from the same songbook, in essence creating chords to strengthen the collective voice of memory. With neural prosthetic technology  microchips that can Âlisten to many neurons at the same time  researchers are able to find correlations between the activity of many nerve cells. ÂUsing that same choir analogy, you can start perceiving some sounds that have a rhythm, a tune and chords that are related to each other: in sum, short–term memories, said Martinez–Trujillo, who is also an associate professor at WesternÂs Schulich School of Medicine & Dentistry.
And while the ramifications of this discovery are still being explored, Âthis gives us good material to work with as we move forward in brain research. It provides us with the necessary knowledge to find ways to manipulate brain circuits and improve short term memory in affected individuals, Martinez–Trujillo said.
ÂThe microchip technology also allows us to extract signals from the brain in order to reverse–engineer brain circuitry and decode the information that is in the subjectÂs mind, said Adam Sachs, neurosurgeon and associate scientist at The Ottawa Hospital and assistant professor at the University of Ottawa Brain and Mind Research Institute. ÂIn the near future, we could use this information to allow cognitive control of neural prosthetics in patients with ALS or severe cervical spinal cord injury.Â
The research was published in the Proceedings of the National Academy of Sciences journal. The research team members were Martinez–Trujillo; Sachs; Matthew Leavitt, a PhD student at the department of physiology at McGill University, Montreal; and Florian Pieper of the department of neuro– and pathophysiology at University Medical Centre Hamburg–Eppendorf in Germany.
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