Abstract
Cortical neurons show distinct firing patterns across multiple task epochs characterized by different computations. Recent studies suggest that such distinct patterns underlie dynamic population code achieving computational flexibility, whereas neurons in some cortical areas often show coherent firing patterns across epochs. To understand how coherent single-neuron code contributes to dynamic population code, we analyzed neural responses in the rat perirhinal cortex (PRC) during cue and reward epochs of a two-alternative forced-choice task. We found that the PRC neurons often encoded the opposite choice directions between those epochs. By using principal component analysis as a population-level analysis, we identified neural subspaces associated with each epoch, which reflected coordination across the neurons. The cue and reward epochs shared neural dimensions where the choice directions were consistently discriminated. Interestingly, those dimensions were supported by dynamically changing contributions of the individual neurons. These results demonstrated heterogeneity of coherent single-neuron representations in their contributions to population code.
Highlights
Cortical neurons show distinct firing patterns across multiple task epochs characterized by different computations
These results suggest the capacity of the perirhinal cortex (PRC) neural population to employ both population dynamics and coherent representations through multiple task epochs
These results suggest that the firings of the PRC neurons are more sensitive to the choice behavior than the cue information
Summary
Cortical neurons show distinct firing patterns across multiple task epochs characterized by different computations. Recent studies have indicated that such diverse singleneuron responses are only interpretable in terms of their contributions to population dynamics which flexibly realize different computations, in association and motor cortices[4,5,6,7,8,9] These studies highlight the complex changes occurring in neural responses across epochs of a given task, which can provide orthogonal neural subspaces for independent computations. It has been shown that individual neurons in the PRC flexibly encode graded visual stimuli during active cue-sampling and response categories during movements for choice[17] These results suggest the capacity of the PRC neural population to employ both population dynamics and coherent representations through multiple task epochs. Our results suggest that individual neurons flexibly coordinate to support computations associated with different epochs, while they are holding temporally coherent representations
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