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Extracellular electrophysiology and two-photon calcium imaging are widely used methods for measuring physiological activity with single-cell resolution across large populations of cortical neurons. While each of these two modalities has distinct advantages and disadvantages, neither provides complete, unbiased information about the underlying neural population. Here, we compare evoked responses in visual cortex recorded in awake mice under highly standardized conditions using either imaging of genetically expressed GCaMP6f or electrophysiology with silicon probes. Across all stimulus conditions tested, we observe a larger fraction of responsive neurons in electrophysiology and higher stimulus selectivity in calcium imaging, which was partially reconciled by applying a spikes-to-calcium forward model to the electrophysiology data. However, the forward model could only reconcile differences in responsiveness when restricted to neurons with low contamination and an event rate above a minimum threshold. This work established how the biases of these two modalities impact functional metrics that are fundamental for characterizing sensory-evoked responses.

Visual behavior requires coordinated activity across hierarchically organized brain circuits. Understanding this complexity demands datasets that are both large-scale (sampling many areas) and dense (recording many neurons in each area). Here we present a database of spiking activity across the mouse visual system-including thalamus, cortex, and midbrain-while mice perform an image change detection task. Using Neuropixels probes, we record from >75,000 high-quality units in 54 mice, mapping area-, cortical layer-, and cell type-specific coding of sensory and motor information. Modulation by task-engagement increased across the thalamocortical hierarchy but was strongest in the midbrain. Novel images modulated cortical (but not thalamic) responses through delayed recurrent activity. Population decoding and optogenetics identified a critical decision window for change detection and revealed that mice use an adaptation-based rather than image-comparison strategy. This comprehensive resource provides a valuable substrate for understanding sensorimotor computations in neural networks.

Detecting novel stimuli in the environment is critical for learning and survival, yet the neural basis of novelty processing is not understood. To characterize cell type-specific novelty processing, we surveyed the activity of ~15,000 excitatory and inhibitory neurons in mice performing a visual task with novel and familiar stimuli. Clustering revealed a dozen functional neuron types defined by experience-dependent encoding. Vasoactive-intestinal-peptide (Vip) expressing inhibitory neurons were diverse, encoding novel stimuli, omissions of familiar stimuli, or behavioral features. Distinct Somatostatin (Sst) expressing inhibitory neurons encoded either familiar or novel stimuli. Subsets of excitatory neurons co-clustered with specific Vip or Sst subpopulations, while Sst and Vip inhibitory clusters were non-overlapping. This study establishes that novelty processing is mediated by diverse functional neuron types in the visual cortex.Competing Interest StatementThe authors have declared no competing interest.Footnotes* Clustering analysis is now performed on all cell types together instead of each independently; A new figure describing the full open access dataset has been added (Figure 1); Supplementary Text describing the dataset and details of analysis methods has been added; Figures and text have been revised for overall clarity and ease of interpretation* https://allensdk.readthedocs.io/en/latest/visual_behavior_optical_physiology.html* https://doi.org/10.48324/dandi.000711/0.231121.1730

Cortical columns interact through dynamic routing of neuronal activity. Monitoring these interactions in animals performing a behavioral task as close as possible to real time will advance our understanding of cortical computation. We developed the Multiplane Mesoscope which combines three established concepts in microscopy: spatio-temporal multiplexing, remote focusing, and random-access mesoscopy. With the Multiplane Mesoscope, we recorded excitatory and inhibitory neuronal subpopulations simultaneously across two cortical areas and multiple cortical layers in behaving mice. In the context of a visual detection of change task, we used this novel platform to study cortical areas interactions and quantified the cell-type specific distribution of neuronal correlations across a set of visual areas and layers. We found that distinct cortical subnetworks represent expected and unexpected visual events. Our findings demonstrate that expectation violations modify signal routing across cortical columns and establish the Allen Brain Observatory Multiplane Mesoscope as a unique platform to study signal routing across connected pairs of cortical areas. Competing Interest Statement The dual-beam add-on module (D.T., N.O., J.L and P.S.) intellectual property has been licensed to Thorlabs. Inc., by the Allen Institute. Footnotes * the manuscript was restructured to decreased technical details of the microscope design and include additional analysis and figures

Extracellular electrophysiology and two-photon calcium imaging are widely used methods for measuring physiological activity with single cell resolution across large populations of neurons in the brain. While these two modalities have distinct advantages and disadvantages, neither provides complete, unbiased information about the underlying neural population. Here, we compare evoked responses in visual cortex recorded in awake mice under highly standardized conditions using either imaging or electrophysiology. Across all stimulus conditions tested, we observe a larger fraction of responsive neurons in electrophysiology and higher stimulus selectivity in calcium imaging. This work explores which data transformations are most useful for explaining these modality specific discrepancies. We show that the higher selectivity in imaging can be partially reconciled by applying a spikes-to-calcium forward model to the electrophysiology data. However, the forward model could not reconcile differences in responsiveness without sub selecting neurons based on event rate or level of signal contamination. This suggests that differences in responsiveness more likely reflect neuronal sampling bias or cluster merging artifacts during spike sorting of electrophysiological recordings, rather than flaws in event detection from fluorescence time series. This work establishes the dominant impacts of the two modalities' respective biases on a set of functional metrics that are fundamental for characterizing sensory-evoked responses. Competing Interest Statement The authors have declared no competing interest.