Sue Ann Koay scite author profile

To explore theories of predictive coding, we presented mice with repeated sequences of images with novel images sparsely substituted. Under these conditions, mice could be rapidly trained to lick in response to a novel image, demonstrating a high level of performance on the first day of testing. Using 2-photon calcium imaging to record from layer 2/3 neurons in the primary visual cortex, we found that novel images evoked excess activity in the majority of neurons. When a new stimulus sequence was repeatedly presented, a majority of neurons had similarly elevated activity for the first few presentations, which then decayed to almost zero activity. The decay time of these transient responses was not fixed, but instead scaled with the length of the stimulus sequence. However, at the same time, we also found a small fraction of the neurons within the population (~2%) that continued to respond strongly and periodically to the repeated stimulus. Decoding analysis demonstrated that both the transient and sustained responses encoded information about stimulus identity. We conclude that the layer 2/3 population uses a two-channel predictive code: a dense transient code for novel stimuli and a sparse sustained code for familiar stimuli. These results extend and unify existing theories about the nature of predictive neural codes.

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Sequential and efficient neural-population coding of complex task information

Koay

Charles

Thiberge

et al. 2022

Neuron

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Neural Correlates of Cognition in Primary Visual versus Neighboring Posterior Cortices during Visual Evidence-Accumulation-based Navigation

Koay

Thiberge

Brody

et al. 2019

Preprint

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Studies of perceptual decision-making have often assumed that the main role of sensory cortices is to provide sensory input to downstream processes that accumulate and drive behavioral decisions. We performed a systematic comparison of neural activity in primary visual (V1) to secondary visual and retrosplenial cortices, as mice performed a task where they should accumulate pulsatile visual cues through time to inform a navigational decision. Even in V1, only a small fraction of neurons had sensory-like responses to cues. Instead, in all areas neurons were sequentially active, and contained information ranging from sensory to cognitive, including cue timings, evidence, place/time, decision and reward outcome. Per-cue sensory responses were amplitude-modulated by various cognitive quantities, notably accumulated evidence. This inspired a multiplicative feedback-loop circuit hypothesis that proposes a more intricate role of sensory areas in the accumulation process, and furthermore explains a surprising observation that perceptual discrimination deviates from Weber-Fechner Law. Figure 2 . Neural activity in all areas/layers were qualitatively similar, and followed choice-specific sequences of activation throughout the trial. (A)Normalized and trial-averaged activity of cells (rows), for single example imaging sessions in the six recorded areas ( cells respectively). Cells were divided into left-/right-choice 06, 22, 23, 48, 32, 9 n = 1 1 1 1 1 8 preferring populations, and sorted by the location of peak activity in correct preferred-choice trials. Cue-locked cells were separately sorted (red bars). Error trials were excluded in this analysis. (B) Rank of sorted cells vs. the location of peak activity, excluding cue-locked cells. Data were pooled across sessions for a given area (colors) and layer (top vs. bottom plots). (C) Duration of iring ields vs. location of peak activities. The iring ield is de ined as the span of time-points with activity at least half the height of the peak (above baseline) in trial-averaged data. Data were pooled across sessions for a given area/layer. Line: Mean across cells. Bands: S.E.M.

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Amplitude modulations of cortical sensory responses in pulsatile evidence accumulation

Koay

Thiberge

Brody

et al. 2020

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How does the brain internally represent a sequence of sensory information that jointly drives a decision-making behavior? Studies of perceptual decision-making have often assumed that sensory cortices provide noisy but otherwise veridical sensory inputs to downstream processes that accumulate and drive decisions. However, sensory processing in even the earliest sensory cortices can be systematically modified by various external and internal contexts. We recorded from neuronal populations across posterior cortex as mice performed a navigational decision-making task based on accumulating randomly timed pulses of visual evidence. Even in V1, only a small fraction of active neurons had sensory-like responses time-locked to each pulse. Here we focus on how these 'cue-locked' neurons exhibited a variety of amplitude modulations from sensory to cognitive, notably by choice and accumulated evidence. These task-related modulations affected a large fraction of cue-locked neurons across posterior cortex, suggesting that future models of behavior should account for such influences.

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Sue Ann Koay

Geometry of abstract learned knowledge in the hippocampus

Predictive Coding of Novel versus Familiar Stimuli in the Primary Visual Cortex

Sequential and efficient neural-population coding of complex task information

Neural Correlates of Cognition in Primary Visual versus Neighboring Posterior Cortices during Visual Evidence-Accumulation-based Navigation

Amplitude modulations of cortical sensory responses in pulsatile evidence accumulation

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