Your Brain Processes Smells Like Paintings and Symphonies

Your Brain Processes Smells Like Paintings and Symphonies
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New research digs into how your brain processes smells.

What happens when we smell lavender? How does our brain process the essence of its fragrance?

Is it like a painting—a snapshot of the flickering activity of cells—captured in a moment in time? Or like a symphony, an evolving ensemble of different cells working together to capture the scent?

The new study suggests that our brain does both.

“These findings reveal a core principle of the nervous system, flexibility in the kinds of calculations the brain makes to represent aspects of the sensory world,” says Krishnan Padmanabhan, an associate professor of neuroscience at the University of Rochester and senior author of the study in Cell Reports.

“Our work provides scientists with new tools to quantify and interpret the patterns of activity of the brain,” says Padmanabhan.

The researchers developed a model to simulate the workings of the early olfactory system—the network the brain relies on for smelling. Employing computer simulations, they found a specific set of connections, called centrifugal fibers, which carry impulses from other parts of the central nervous system to the early sensory regions of the brain, played a critical role.

These centrifugal fibers act as a switch, toggling between different strategies to efficiently represent smells. When the centrifugal fibers were in one state, the cells in the piriform cortex—where the perception of an odor forms—relied on the pattern of activity within a given instant in time. When the centrifugal fibers were in the other state, the cells in the piriform cortex improved both the accuracy and the speed with which cells detected and classified the smell by relying on the patterns of brain activity across time.

These processes suggest the brain has multiple responses to representing a smell.

In one strategy, the brain uses a snapshot, like a painting or a photograph, at a given moment to capture the essential features of the odor.

In the other strategy, the brain keeps track of the evolving patterns. It is attuned to which cells turn on and off and when—like a symphony.

The mathematical models the researchers developed highlight the critical feature of the nervous system—not only diversity in terms of the components that make up the brain but also how these components work together to help the brain experience the world of smell.

“These mathematical models reveal critical aspects of how the olfactory system in the brain might work and could help build brain-inspired artificial computing systems,” Padmanabhan says.

“Computational approaches inspired by the circuits of the brain such as this have the potential to improve the safety of self-driving cars, or help computer vision algorithms more accurately identify and classify objects in an image.”

Funding for the research came from the National Institutes of Health, the National Science Foundation, the Cystinosis Research Foundation, and the Del Monte Institute Pilot Program.

This article was originally published by University of Rochester. Republished via Futurity.org under Creative Commons License 4.0.
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