Which types of brain activity support conscious experiences?

Consciousness remains one of the brain’s biggest mysteries. We know very little about how it emerges from activity within the brain, but most neuroscientists agree consciousness is dynamic in nature.,

Which types of brain activity support conscious experiences?
Schematic of the dynamic core hypothesis (a), with each circle representing a neuron or groups of neurons, and the links between them transient synchronization. Temporally evolving assemblies (b) can be represented as modules unfolding within a multilayer network. Credit: Sofia Morena del Pozo, Helmut Laufs, Vincent Bonhomme, Steven Laureys, Pablo Balenzuala, and Enzo Tagliazucchi

Consciousness remains one of the brain’s biggest mysteries. We know very little about how it emerges from activity within the brain, but most neuroscientists agree consciousness is dynamic in nature.

Our subjective experience doesn’t appear to us like a sequence of disjointed snapshots. Instead, we feel the world as a continuous stream of information. This information is integrated, since we don’t perceive a different stream per –one for vision, one for hearing, and so forth–but as a single one where all percepts merge.

In Chaos, researchers explore the question: Which characteristics should have to support this type of conscious experiences?

“We conclude that brain activity should be integrated, with multiple regions ‘talking to each other’ frequently,” said Enzo Tagliazucchi, a co-author from Universidad Adolfo Ibanez and the Latin American Brain Health Institute in Santiago, Chile. “At the same , the regions involved should change continuously, accounting for the multiplicity of contents that appear in our .”

The group searched for integrated structures that encompass most of the brain but change configuration from time to time. Their hypothesis was these structures should vanish during states of deep unconsciousness, such as deep sleep or while under general anesthetics.

“In the case of the brain, nodes are specific anatomical regions and links indicate brain activity measured at those regions is significantly synchronized,” said Tagliazucchi. “At a given time, we have a describing how are synchronized, and this network changes in time as brainwide communication patterns also change.”

The group wanted to zero in on groups of nodes tightly coupled together (modules) that maintain their identity over time, yet the involved nodes change as time progresses.

“We hypothesize that the largest of these modules is important for consciousness, since it is both dynamic and integrates a large proportion of brain regions,” Tagliazucchi said.

To put it to the test, they developed a way to detect these structures within temporal networks by using current algorithms within certain parameters. The researchers built artificial time-evolving networks to test and benchmark these algorithms and find the optimal parameters.

They applied algorithms using these parameters to brain imaging data and confirmed several hypotheses.

Brain activity during conscious wakefulness presents large integrated and dynamic network modules. These modules tend to vanish or fragment during sleep or under general anesthesia. These changes are similar between both conditions, suggesting unconsciousness occurs in both situations following the same mechanism.

“We expect our methodological advances will help other scientists detect integrated structures within other temporal networks by means of hypothesis-driven parameter optimization,” said Tagliazucchi. “Concerning the neurobiological significance of our findings, I would like to see our results replicated in other unconscious states and different modal organisms and be validated using metrics that do not come from neuroimaging, such as behavioral observations.”


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More information:
“Unconsciousness reconfigures modular brain network dynamics” Chaos, 2021. aip.scitation.org/doi/10.1063/5.0046047

Journal information:
Chaos

Provided by
American Institute of Physics

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