Certain Brain Waves Aren’t Just Background Noise

Summary: Findings shed new light on how brain states are regulated and how the brain can switch between them.

Source: University of Oregon

Even when at rest, the brain is never truly quiet.

New research in mice sheds light on the seemingly random brain signals that hum in the background of brains. These signals might help the brain switch between states of inattention or disengagement and states of optimal performance, UO researchers reported Oct. 14 in the journal Neuron.

Neuroscientists have been studying an oscillating background wave called the alpha rhythm in the human brain for decades. This signal appears to reflect whether a person is engaged and attentive or not, but the neurobiological basis for the signal isn’t fully understood.

“Brain states have big effects on how you can think and perform,” said UO neuroscientist and Presidential Chair David McCormick, who led the new study with postdoctoral researcher Dennis Nestvogel.

If the brain is idling in background mode, it’s processing information less efficiently, making it harder to do something that requires deep focus. On the other hand, if the brain is too amped up, it might not perform at its best either. Understanding how these brain states are regulated, and how the brain can switch between them, might help scientists learn more about focus, attention and engagement.

In their study, McCormick and Nestvogel looked at a background firing pattern in mice brains that is similar to the human alpha rhythm. By recording animals’ neural activity while they explored, the researchers could link the patterns of brain waves to behavior. They watched the rhythm appear when the mice were relaxing, then disappear when the animals were moving around or twitching their noses and whiskers.

That pattern of neural firing in an at-rest brain comes from a communication volley between two different brain regions, the thalamus and the cortex, the pair showed.

“We’ve known the thalamus is important for sleep,” Nestvogel said. “But not much is known about how the thalamus may control moment-to-moment changes in waking states.”

The thalamus is like a switchboard in the brain: It takes in signals from many different brain regions, and routes them out again. The particular neurons at play here “can send two different types of signals: They can rhythmically discharge in a resting hum, or they can switch to information-transmitting mode,” McCormick said. And mice could switch between those two states within milliseconds, the team noticed.

When the researchers silenced activity from the thalamus, the cortex couldn’t switch into the more attentive, information-sending state. Instead, the background signals were reminiscent of the patterns seen when mice are drowsy or sleeping.

Going forward, McCormick and Nestvogel hope to learn more about the origins of these background rhythms in the brain and better understand how they affect performance. Ultimately, knowing how these brain circuits work help might lead to better treatments for ADHD and other disorders that affect attention and focus.

“In the past, people thought that most of the spontaneous rhythms in the awake brain constitute random noise,” Nestvogel said. “We still don’t fully know their purpose, but we can now better predict these signals and see their effects on information processing and behavior.”

New research in mice sheds light on the seemingly random brain signals that hum in the background of brains. These signals might help the brain switch between states of inattention or disengagement and states of optimal performance, UO researchers reported Oct. 14 in the journal Neuron.

Neuroscientists have been studying an oscillating background wave called the alpha rhythm in the human brain for decades. This signal appears to reflect whether a person is engaged and attentive or not, but the neurobiological basis for the signal isn’t fully understood.

“Brain states have big effects on how you can think and perform,” said UO neuroscientist and Presidential Chair David McCormick, who led the new study with postdoctoral researcher Dennis Nestvogel.

If the brain is idling in background mode, it’s processing information less efficiently, making it harder to do something that requires deep focus. On the other hand, if the brain is too amped up, it might not perform at its best either. Understanding how these brain states are regulated, and how the brain can switch between them, might help scientists learn more about focus, attention and engagement.

In their study, McCormick and Nestvogel looked at a background firing pattern in mice brains that is similar to the human alpha rhythm. By recording animals’ neural activity while they explored, the researchers could link the patterns of brain waves to behavior. They watched the rhythm appear when the mice were relaxing, then disappear when the animals were moving around or twitching their noses and whiskers.

This shows the outline of a head
Neuroscientists have been studying an oscillating background wave called the alpha rhythm in the human brain for decades. Image is in the public domain

That pattern of neural firing in an at-rest brain comes from a communication volley between two different brain regions, the thalamus and the cortex, the pair showed.

“We’ve known the thalamus is important for sleep,” Nestvogel said. “But not much is known about how the thalamus may control moment-to-moment changes in waking states.”

The thalamus is like a switchboard in the brain: It takes in signals from many different brain regions, and routes them out again. The particular neurons at play here “can send two different types of signals: They can rhythmically discharge in a resting hum, or they can switch to information-transmitting mode,” McCormick said. And mice could switch between those two states within milliseconds, the team noticed.

When the researchers silenced activity from the thalamus, the cortex couldn’t switch into the more attentive, information-sending state. Instead, the background signals were reminiscent of the patterns seen when mice are drowsy or sleeping.

Going forward, McCormick and Nestvogel hope to learn more about the origins of these background rhythms in the brain and better understand how they affect performance. Ultimately, knowing how these brain circuits work help might lead to better treatments for ADHD and other disorders that affect attention and focus.

“In the past, people thought that most of the spontaneous rhythms in the awake brain constitute random noise,” Nestvogel said. “We still don’t fully know their purpose, but we can now better predict these signals and see their effects on information processing and behavior.”

About this neuroscience research news

Author: Laurel Hamers
Source: University of Oregon
Contact: Laurel Hamers – University of Oregon
Image: The image is in the public domain

Original Research: Closed access.
Visual thalamocortical mechanisms of waking state-dependent activity and alpha oscillations” by Dennis B. Nestvogel et al. Neuron


Abstract

Visual thalamocortical mechanisms of waking state-dependent activity and alpha oscillations

Highlights

  • Whisker movements correlate with rapid synaptic activity in V1 and visual thalamus
  • Silencing of V1 does not abolish movement-related activity in most dLGN or LP cells
  • Silencing of visual thalamus strongly reduces movement-related activation in V1
  • Thalamocortical interactions generate state-dependent alpha frequency oscillation

Summary

The brain exhibits distinct patterns of recurrent activity closely related to behavioral state. The neural mechanisms that underlie state-dependent activity in the awake animal are incompletely understood.

Here, we demonstrate that two types of state-dependent activity, rapid arousal/movement-related signals and a 3–5 Hz alpha-like rhythm, in the primary visual cortex (V1) of mice strongly correlate with activity in the visual thalamus.

Inactivation of V1 does not interrupt arousal/movement signals in most visual thalamic neurons, but it abolishes the 3–5 Hz oscillation. Silencing of the visual thalamus similarly eradicates the alpha-like rhythm and perturbs arousal/movement-related activation in V1. Intracellular recordings in thalamic neurons reveal the 3–5 Hz oscillation to be associated with rhythmic low-threshold Ca2+ spikes.

Our results indicate that thalamocortical interactions through ionotropic signaling, together with cell-intrinsic properties of thalamocortical cells, play a crucial role in shaping state-dependent activity in V1 of the awake animal.

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