Where Does Consciousness Reside in the Brain? New Discovery Helps Pinpoint Its Location
The researchers used mouse “brain maps” to pinpoint consciousness.
A recent study has identified brain network cores with strong bidirectional connections.
Science may be getting closer to figuring out where consciousness resides in the brain. New research demonstrates the significance of certain kinds of neural connections in identifying consciousness.
Jun Kitazono, a corresponding author of the study and project researcher at the Department of General Systems Studies at the University of Tokyo, conducted the study, which was published in the journal Cerebral Cortex.
“Where in the brain consciousness resides has been one of the biggest questions in science,” said Associate Professor Masafumi Oizumi, corresponding author and head of the lab conducting the study. “Although we have not reached a conclusive answer, much empirical evidence has been accumulated in the course of searching for the minimal mechanisms sufficient for conscious experience, or the neural correlates of consciousness.”
It has been suggested that the part of the brain network supporting consciousness brain regions should be bidirectionally connected because both feed-forward and feedback processes are necessary for conscious experience. For example, previous studies examining visual perception have shown that conscious perception does not arise when there is only feed-forward processing, whereas it arises when there is feedback as well as feed-forward processing. Credit: ©2022 Jun Kitazono
The researchers made a step toward discovering the minimally sufficient subnetworks in the brain that support conscious experience with this study.
The researchers looked for one particular hallmark of consciousness within the neural networks of the brain, bidirectional pathways, to pinpoint the parts of the brain where awareness resides. Our brains process information when we see something or experience something. This is known as a feed-forward signal, however receiving such signals is insufficient for consciousness. Our brains must also convey information back to us in what is known as feedback. Not every area of the brain can receive and respond to feed-forward information. Researchers hypothesized that these bidirectional connections are an essential hallmark of the parts of the brain responsible for consciousness.
The proposed algorithm can decompose the entire network hierarchically, into the network part with the strongest bidirectional connections, the part with the second strongest, and so on down the line. Credit: ©2022 Jun Kitazono
“Feed-forward processing alone is insufficient for subjects to consciously perceive stimuli; rather, feedback is also necessary, indicating the need for bidirectional processing. The feedback component disappears not only during the loss of specific contents of consciousness in awake states, but also during unconscious states where conscious experiences are generally lost, such as general anesthesia, sleep, and vegetative states,” said Kitazono. He also explained that it does not matter if you are looking at a human, monkey, mouse, bird, or fly; the bi-directionality of processing remains essential.
Researchers used a mouse connectome and computational techniques to test their idea. A connectome is a detailed map of the connections in the brain. First, they developed an efficient algorithm to extract the parts of the brain with strong bidirectional connections, called complexes. Then, they applied the algorithm to the mouse connectome.
Conventional neuroscience has studied the relationship of what kind of brain activity r occurs in response to an external stimulus s (e.g., an image of an apple). If we write this relationship using the function f as r=f(s), we can say that clarifying the function f is the main research that conventional neuroscience has been doing. Such research has revealed much about the mechanism of information processing, that is, how the brain processes information from external stimuli. On the other hand, our brain not only processes information from the external world but also produces the subjective experience of “seeing an apple.” The ultimate goal of the Oizumi Lab is to theoretically understand the subjective experience and consciousness produced by the brain: that is, to clarify the function g that connects brain activity r and consciousness C, where C is the consciousness produced from brain activity r (C=g(r)). Credit: ©2022 Masafumi Oizumi
“We found that the extracted complexes with the most bidirectionality were not evenly distributed among all major regions, but rather are concentrated in the cortical regions and thalamic regions,” said Kitazono. “On the other hand, regions in the other major regions have low bi-directionality. In particular, regions in the cerebellum have much lower bidirectionality.”
These findings align with where scientists have long thought consciousness resides in the brain. The cerebral cortex, located on the surface of the brain, contains sensory areas, motor areas and association areas that are thought to be essential to consciousness experience. The thalamus, located in the middle of the brain, has likewise been thought to be related to consciousness, and in particular, the interaction between the thalamus and cortical regions, called the thalamocortical loop, is considered important for consciousness. These results support the idea that the bi-directionality in the brain network is a key to identifying the place of consciousness.
Researchers emphasized that they are still working toward identifying the place of consciousness.
“This study focuses only on ‘static’ anatomical connections between neurons or brain areas. However, consciousness is ‘dynamic,’ changing from moment to moment depending on neural activity,” said Oizumi. “Although anatomical connections tell us how neural activity would propagate and how brain areas would interact, we need to directly investigate the dynamics of neural activity to identify the place of consciousness at any given moment.”
As a next step, he said the team is currently analyzing activity-based networks of the brain in various types of neural recordings.
“The ultimate goal of our lab is to find the mathematical relationship between consciousness and the brain,” said Oizumi. “In this study, we have attempted to relate the network properties of the brain to the place of consciousness. We will further investigate the relationship between consciousness and the brain, toward what is our ultimate goal.”
Reference: “Bidirectionally connected cores in a mouse connectome: towards extracting the brain subnetworks essential for consciousness” by Jun Kitazono, Yuma Aoki and Masafumi Oizumi, 21 July 2022, Cerebral Cortex.
DOI: 10.1093/cercor/bhac143
The researchers used mouse “brain maps” to pinpoint consciousness.
A recent study has identified brain network cores with strong bidirectional connections.
Science may be getting closer to figuring out where consciousness resides in the brain. New research demonstrates the significance of certain kinds of neural connections in identifying consciousness.
Jun Kitazono, a corresponding author of the study and project researcher at the Department of General Systems Studies at the University of Tokyo, conducted the study, which was published in the journal Cerebral Cortex.
“Where in the brain consciousness resides has been one of the biggest questions in science,” said Associate Professor Masafumi Oizumi, corresponding author and head of the lab conducting the study. “Although we have not reached a conclusive answer, much empirical evidence has been accumulated in the course of searching for the minimal mechanisms sufficient for conscious experience, or the neural correlates of consciousness.”
It has been suggested that the part of the brain network supporting consciousness brain regions should be bidirectionally connected because both feed-forward and feedback processes are necessary for conscious experience. For example, previous studies examining visual perception have shown that conscious perception does not arise when there is only feed-forward processing, whereas it arises when there is feedback as well as feed-forward processing. Credit: ©2022 Jun Kitazono
The researchers made a step toward discovering the minimally sufficient subnetworks in the brain that support conscious experience with this study.
The researchers looked for one particular hallmark of consciousness within the neural networks of the brain, bidirectional pathways, to pinpoint the parts of the brain where awareness resides. Our brains process information when we see something or experience something. This is known as a feed-forward signal, however receiving such signals is insufficient for consciousness. Our brains must also convey information back to us in what is known as feedback. Not every area of the brain can receive and respond to feed-forward information. Researchers hypothesized that these bidirectional connections are an essential hallmark of the parts of the brain responsible for consciousness.
The proposed algorithm can decompose the entire network hierarchically, into the network part with the strongest bidirectional connections, the part with the second strongest, and so on down the line. Credit: ©2022 Jun Kitazono
“Feed-forward processing alone is insufficient for subjects to consciously perceive stimuli; rather, feedback is also necessary, indicating the need for bidirectional processing. The feedback component disappears not only during the loss of specific contents of consciousness in awake states, but also during unconscious states where conscious experiences are generally lost, such as general anesthesia, sleep, and vegetative states,” said Kitazono. He also explained that it does not matter if you are looking at a human, monkey, mouse, bird, or fly; the bi-directionality of processing remains essential.
Researchers used a mouse connectome and computational techniques to test their idea. A connectome is a detailed map of the connections in the brain. First, they developed an efficient algorithm to extract the parts of the brain with strong bidirectional connections, called complexes. Then, they applied the algorithm to the mouse connectome.
Conventional neuroscience has studied the relationship of what kind of brain activity r occurs in response to an external stimulus s (e.g., an image of an apple). If we write this relationship using the function f as r=f(s), we can say that clarifying the function f is the main research that conventional neuroscience has been doing. Such research has revealed much about the mechanism of information processing, that is, how the brain processes information from external stimuli. On the other hand, our brain not only processes information from the external world but also produces the subjective experience of “seeing an apple.” The ultimate goal of the Oizumi Lab is to theoretically understand the subjective experience and consciousness produced by the brain: that is, to clarify the function g that connects brain activity r and consciousness C, where C is the consciousness produced from brain activity r (C=g(r)). Credit: ©2022 Masafumi Oizumi
“We found that the extracted complexes with the most bidirectionality were not evenly distributed among all major regions, but rather are concentrated in the cortical regions and thalamic regions,” said Kitazono. “On the other hand, regions in the other major regions have low bi-directionality. In particular, regions in the cerebellum have much lower bidirectionality.”
These findings align with where scientists have long thought consciousness resides in the brain. The cerebral cortex, located on the surface of the brain, contains sensory areas, motor areas and association areas that are thought to be essential to consciousness experience. The thalamus, located in the middle of the brain, has likewise been thought to be related to consciousness, and in particular, the interaction between the thalamus and cortical regions, called the thalamocortical loop, is considered important for consciousness. These results support the idea that the bi-directionality in the brain network is a key to identifying the place of consciousness.
Researchers emphasized that they are still working toward identifying the place of consciousness.
“This study focuses only on ‘static’ anatomical connections between neurons or brain areas. However, consciousness is ‘dynamic,’ changing from moment to moment depending on neural activity,” said Oizumi. “Although anatomical connections tell us how neural activity would propagate and how brain areas would interact, we need to directly investigate the dynamics of neural activity to identify the place of consciousness at any given moment.”
As a next step, he said the team is currently analyzing activity-based networks of the brain in various types of neural recordings.
“The ultimate goal of our lab is to find the mathematical relationship between consciousness and the brain,” said Oizumi. “In this study, we have attempted to relate the network properties of the brain to the place of consciousness. We will further investigate the relationship between consciousness and the brain, toward what is our ultimate goal.”
Reference: “Bidirectionally connected cores in a mouse connectome: towards extracting the brain subnetworks essential for consciousness” by Jun Kitazono, Yuma Aoki and Masafumi Oizumi, 21 July 2022, Cerebral Cortex.
DOI: 10.1093/cercor/bhac143
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