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  1. Live 016ebeee836f
    5/17/2026, 4:35:28 PM
    Content snapshot
    {
      "kind": "infographic",
      "prompt": "Gamma oscillation frequency ranges associated with different interneuron subtypes",
      "provider": "other",
      "raw_fields": {
        "title": "Gamma oscillation frequency ranges associated with different interneuron subtypes",
        "papers": [
          {
            "n": 4,
            "doi": "10.1038/nature08002",
            "value": "20-80 Hz (gamma amplification by FS/PV)",
            "cite_key": "Cardin2009",
            "study_system": "mouse barrel cortex in vivo",
            "value_source_sentence": "Cortical gamma oscillations (20–80 Hz) predict increases in focused attention, and failure in gamma regulation is a hallmark of neurological and psychiatric disease."
          },
          {
            "n": 32,
            "doi": "10.1038/nn.4562",
            "value": "~30 Hz (SOM-dependent context-dependent gamma)",
            "cite_key": "Veit2017",
            "study_system": "mouse V1 in vivo",
            "value_source_sentence": "As we increased the size of the visual stimulus we observed a large, nearly monotonic increase in power in a narrow band of the low gamma range (peak frequency at 21 degrees: 32±1 Hz, n = 32 mice)."
          },
          {
            "n": 23,
            "doi": "10.1016/j.neuron.2017.11.033",
            "value": "SOM: 5-30 Hz beta band; PV: 20-80 Hz broadband",
            "cite_key": "Chen2017",
            "study_system": "mouse V1 in vivo (behaving)",
            "value_source_sentence": "Rhythmic activation of SOM and PV cells in the local circuit entrains resonant activity in the narrow 5- to 30-Hz band and the wide 20- to 80-Hz band, respectively."
          },
          {
            "n": null,
            "doi": "10.1016/j.neuron.2022.10.036",
            "value": "25-40 Hz (VIP modulates gamma power locally)",
            "cite_key": "Veit2023",
            "study_system": "mouse V1 in vivo",
            "value_source_sentence": "In the mouse primary visual cortex, a visually induced gamma oscillation (25–40 Hz), similar to the widely studied gamma rhythms in higher mammals, requires the activity of somatostatin-positive interneurons."
          }
        ],
        "figure_id": "fig_gamma_frequency_by_cell_type",
        "n_analyzed": "varies by study",
        "description": "Comparison of gamma frequency ranges reported across studies for PV-driven vs SST-driven oscillations",
        "n_definition": "varies: mice, tagged neurons",
        "scope_region": "mouse visual and barrel cortex",
        "comparison_type": "cross_study_quantitative",
        "taxonomic_level": "cell type (PV/SST/VIP)",
        "scope_population": "interneuron subtypes (PV, SST, VIP)",
        "homogeneity_check": "Moderate comparability. All mouse studies but different cortical areas (V1 vs barrel cortex), different stimulus paradigms, and different definitions of gamma band. The Chen et al. gamma (~30Hz) may be a distinct oscillation from the Cardin et al. gamma (20-80Hz broadband)."
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      "section_title": "Cell-Type-Specific Inhibition in Cortical Processing",
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          "Local review repositories are read-only inputs.",
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