Scientists have gained new insights into how neurons in the brain communicate during a decision, and how the connections between neurons may help reinforce a choice.
The study — conducted in mice and led by neuroscientists is the first to combine structural, functional, and behavioral analyses to explore how neuron-to-neuron connections support decision-making. The findings appear in the journal Nature.
“How the brain is organized to help make decisions is a big, fundamental question, and the neural circuitry — how neurons are connected to one another — in brain areas that are important for decision-making isn’t well understood,” said a co-senior author on the paper.
In the research, mice were tasked with choosing which way to go in a maze to find a reward. The researchers found that a mouse’s decision to go left or right activated sequential groups of neurons, culminating in the suppression of neurons linked to the opposite choice.
These specific connections between groups of neurons may help sculpt decisions by shutting down neural pathways for alternative options, the author said.
The other co-seniors lab uses mice to study behavioral and functional aspects of decision-making. Typical experiments involve placing a mouse in a virtual reality maze and recording neural activity as it makes decisions. Such experiments have shown that distinct, but intermingled, sets of neurons fire when an animal chooses left versus right.
The new study focused on a region of the brain called the posterior parietal cortex — what the authors describe as an “integrative hub” that receives and processes information gathered by multiple senses to help animals make decisions.
“We were interested in understanding how neural dynamics arise in this brain area that is important for navigational decision-making,” co-senior author said. “We’re looking for rules of connectivity — simple principles that provide a foundation for the brain’s computations as it makes decisions.”
The lab recorded neural activity as mice ran a T-shaped maze in virtual reality. A cue, which happened several seconds beforehand, indicated to the mice whether a reward would be in the left or right arm of the T. The Lee lab used powerful microscopes to map the structural connections between the same neurons recorded during the maze task.
By combining modalities, the researchers distinguished excitatory neurons — those that activate other cells — from inhibitory neurons, which suppress other cells. They found that a specific set of excitatory neurons fired when a mouse decided to turn right, and these “right-turn” neurons activated a set of inhibitory neurons that curbed activity in “left-turn” neurons. The opposite was true when a mouse decided to turn left.
“As the animal is expressing one choice, the wiring of the neuronal circuit may help stabilize that choice by suppressing other choices,” the author said. “This could be a mechanism that helps an animal maintain a decision and prevents ‘changes of mind’.”
The findings need to be confirmed in humans, although the authors expect that there is some conservation across species.
The researchers see many directions for future research. One is exploring the connections between neurons involved in decision-making in other brain regions.
We used these combined experimental techniques to find one rule of connectivity, and now we want to find others,” the author said.
https://www.nature.com/articles/s41586-024-07088-7
How does the brain make decisions?
- 1,007 views
- Added
Edited
Latest News
Common brain network detect…
By newseditor
Posted 04 Oct
Mechanism behind autophagy…
By newseditor
Posted 04 Oct
Activation of parkin by a m…
By newseditor
Posted 04 Oct
A new pathway involved in a…
By newseditor
Posted 03 Oct
Antidepressant shows promis…
By newseditor
Posted 03 Oct
Other Top Stories
Regenerating damaged lungs for transplantation!
Read more
Sweet taste neurons identified!
Researchers identify the neurons responsible for relaying sweet taste signals to the gustatory thalamus and cortex in mice.
While the peripheral taste system has been extensively investigated, relatively little is known about the contribution of CNS gustatory neurons in the sensation of taste. In this new study, researchers have identified neurons in the brainstem that are responsible for encoding…
Read more
Gene therapy heals damage caused by heart attack
Read more
Mechanism blocking retinal regeneration uncovered!
Read more
Fooling nerve cells into acting normal
Read more
Protocols
Use of synthetic circular R…
By newseditor
Posted 06 Oct
The gut-brain axis in depre…
By newseditor
Posted 04 Oct
Droplet-based functional CR…
By newseditor
Posted 03 Oct
Multi-peptide characterizat…
By newseditor
Posted 24 Sep
Nanoplasmonic aptasensor fo…
By newseditor
Posted 20 Sep
Publications
Catchers of folding gone aw…
By newseditor
Posted 05 Oct
Targeting conserved TIM3+VI…
By newseditor
Posted 05 Oct
The androgen receptor in me…
By newseditor
Posted 04 Oct
A potential target for noni…
By newseditor
Posted 04 Oct
Palmitoylation of ULK1 by Z…
By newseditor
Posted 04 Oct
Presentations
Hydrogels in Drug Delivery
By newseditor
Posted 12 Apr
Lipids
By newseditor
Posted 31 Dec
Cell biology of carbohydrat…
By newseditor
Posted 29 Nov
RNA interference (RNAi)
By newseditor
Posted 23 Oct
RNA structure and functions
By newseditor
Posted 19 Oct
Posters
A chemical biology/modular…
By newseditor
Posted 22 Aug
Single-molecule covalent ma…
By newseditor
Posted 04 Jul
ASCO-2020-HEALTH SERVICES R…
By newseditor
Posted 23 Mar
ASCO-2020-HEAD AND NECK CANCER
By newseditor
Posted 23 Mar
ASCO-2020-GENITOURINARY CAN…
By newseditor
Posted 23 Mar