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Neural structure of a sensory decoder for motor control

Medicine and Health

Neural structure of a sensory decoder for motor control

S. W. Egger and S. G. Lisberger

This groundbreaking research by Seth W. Egger and Stephen G. Lisberger unveils the neural intricacies behind transforming sensory inputs into smooth pursuit eye movements, revealing how target size disrupts established psychophysical norms. Discover a novel model that redefines our understanding of sensory decoding!... show more
Abstract
The transformation of sensory input to motor output is often conceived as a decoder operating on neural representations. We seek a mechanistic understanding of sensory decoding by mimicking neural circuitry in the decoder’s design. The results of a simple experiment shape our approach. Changing the size of a target for smooth pursuit eye movements changes the relationship between the variance and mean of the evoked behavior in a way that contradicts the regime of “signal-dependent noise” and defies traditional decoding approaches. A theoretical analysis leads us to propose a circuit for pursuit that includes multiple parallel pathways and multiple sources of variation. Behavioral and neural responses with biomimetic statistics emerge from a biologically-motivated circuit model with noise in the pathway that is dedicated to flexibly adjusting the strength of visual-motor transmission. Our results demonstrate the power of re-imagining decoding as processing through the parallel pathways of neural systems.
Publisher
Nature Communications
Published On
Apr 05, 2022
Authors
Seth W. Egger, Stephen G. Lisberger
DOI
https://doi.org/10.1038/s41467-022-29457-4
Tags
neural mechanisms
smooth pursuit eye movements
target size
behavioral variance
psychophysical laws
parallel processing
gain control

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