Project Summary/Abstract
In a world filled with sensory information, the ability to filter out repetitive or redundant stimuli while still
maintaining the ability to detect change in the environment is critical to biological success. Studies have
characterized reduced cortical responses to repetitive stimuli (adaptation) and augmented cortical responses to
stimuli that differ from these expected regularities (novelty detection); however, the cortical circuits that enable
flexibly encoding stimuli based on the context in which they are experienced remain unknown. Disinhibitory
microcircuits, especially those mediated by vasoactive intestinal polypeptide-expressing inhibitory interneurons
(VIPs), may play a role in this flexible coding by altering the inhibition supplied to principal excitatory neurons
(PYRs) in neocortex. Despite this, the relationship between neural activity of VIPs and PYRs during adaptation
and novelty detection remain poorly understood.
In this proposal, I seek to use fast dual-color, three-dimensional, two-photon calcium imaging to
simultaneously monitor neural activity of both VIPs and PYRs in primary visual cortex during a classic visual
“oddball” paradigm (Aim 1). This paradigm presents the same stimulus in control, repetitive, and rare/deviant
contexts, which enables directly recording neural responses to the same stimulus when it is an established
regularity and when it is novel and thus deviates from established regularity. I will then use data and theory
analysis tools to computationally model neocortical adaptation and novelty detection (Aim 2) by incorporating
anatomical and neural recording data from PYRs and interneuron populations (including VIPs), which are often
excluded from network models. The creation of this holistic model is likely to reveal fundamental circuitry that
gives rise to flexible neural encoding of sensory stimuli. Finally, I will integrate optogenetic interventional tools
for circuit manipulation with two-photon imaging to directly test the relationship between VIP neural activity and
adaptation and novelty detection in PYRs. Altogether, these aims directly address several of the BRAIN Initiative
2025 high priority goals: monitor neural activity, interventional tools, data and theory analysis, and integrated
approaches. Furthermore, the experiments proposed under these aims will result in significant technical and
theoretical training for the applicant and will advance essential understanding of how excitatory, inhibitory, and
disinhibitory circuits across cortical layers diverge in their dynamic neural activity and differentially contribute to
sensory processing.