Version history

1 version on record. Newest first; the live version sits at the top with a live indicator.

  1. Live 302b6e6e3471
    5/17/2026, 4:35:28 PM
    Content snapshot
    {
      "kind": "infographic",
      "prompt": "Converging evidence across brain regions shows that SST-mediated dendritic inhibition is a gating mechanism for synaptic plasticity, with release from SST inhibition enabling dendritic calcium events required for LTP.",
      "provider": "other",
      "raw_fields": {
        "papers": [
          {
            "doi": "10.1038/nn.3024",
            "value": "SST provides tunable dendritic inhibition regulating input transformations",
            "method": "in vitro optogenetics and electrophysiology",
            "metric": "SST gating of dendritic integration",
            "cite_key": "LovettBarron2012",
            "condition": "SST activation/silencing",
            "study_system": "mouse hippocampus CA1",
            "value_source_sentence": "Regulation of neuronal input transformations by tunable dendritic inhibition"
          },
          {
            "doi": "10.1126/science.1247485",
            "value": "SST silencing impairs contextual fear memory formation",
            "method": "in vivo optogenetics, fear conditioning",
            "metric": "SST necessity for fear learning",
            "cite_key": "LovettBarron2014",
            "condition": "SST silencing during conditioning",
            "study_system": "mouse hippocampus CA1",
            "value_source_sentence": "Dendritic inhibition in the hippocampus supports fear learning"
          },
          {
            "doi": "10.1523/jneurosci.1369-21.2021",
            "value": "VIP activation via SST inhibition gates associative LTP",
            "method": "in vitro optogenetics",
            "metric": "VIP-SST disinhibition enables LTP",
            "cite_key": "CantoBustos2022",
            "condition": "VIP activation during LTP induction",
            "study_system": "mouse piriform cortex",
            "value_source_sentence": "LTP is gated by the inactivation SST or PV interneurons and by the activation of VIP interneurons"
          },
          {
            "doi": "10.1038/nature13664",
            "value": "Sensory-evoked dendritic plateau potentials drive LTP in vivo",
            "method": "in vivo electrophysiology",
            "metric": "Dendritic plateau potentials drive LTP",
            "cite_key": "Gambino2014",
            "condition": "sensory stimulation",
            "study_system": "mouse barrel cortex L2/3",
            "value_source_sentence": "Sensory-evoked LTP driven by dendritic plateau potentials in vivo"
          },
          {
            "doi": "10.1038/s41467-025-64859-0",
            "value": "OLM interneurons regulate place cell plasticity and remapping",
            "method": "in vivo electrophysiology and optogenetics",
            "metric": "OLM SST gating of place cell plasticity",
            "cite_key": "Udakis2025",
            "condition": "spatial exploration",
            "study_system": "mouse hippocampus CA1",
            "value_source_sentence": "OLM interneurons selectively target inhibition to the distal dendrites of CA1 pyramidal cells"
          }
        ],
        "comparison_id": "dendritic-inhibition-and-plasticity",
        "comparison_name": "SST-Mediated Dendritic Inhibition Gates Synaptic Plasticity Across Brain Regions",
        "comparison_type": "convergent evidence",
        "what_it_reveals": "Converging evidence across brain regions shows that SST-mediated dendritic inhibition is a gating mechanism for synaptic plasticity, with release from SST inhibition enabling dendritic calcium events required for LTP.",
        "homogeneity_check": {
          "caveats": [
            "Different brain regions (hippocampus, piriform, barrel cortex)",
            "Different plasticity paradigms",
            "Mix of in vitro and in vivo",
            "Different measures of plasticity"
          ],
          "comparable": false
        },
        "suggested_plot_type": "forest plot"
      },
      "section_id": "section_07_evidence_package",
      "source_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewSST/blob/89b7e9787cd90e942b0adb531d549af3ddad30f1/evidence/section_07_evidence_package.json",
      "target_ref": "wiki_page:computationalreviewsst-07",
      "review_repo": "ComputationalReviewSST",
      "section_ref": "wiki_page:computationalreviewsst-07",
      "source_path": "evidence/section_07_evidence_package.json",
      "source_refs": [
        "paper:paper-28660a26542f",
        "paper:paper-7c1701946c71",
        "paper:paper-88ec00d4653f",
        "paper:paper-8bdf7e3be782",
        "paper:paper-e9f2f58c35e6"
      ],
      "section_title": "Circuit Motifs and Dendritic Computation",
      "source_policy": {
        "mode": "public_source_pointer_with_short_context",
        "notes": [
          "Local review repositories are read-only inputs.",
          "SciDEX stores paper metadata, structured evidence, file pointers, and short citation contexts; it does not copy full review prose."
        ],
        "source_commit_sha": "89b7e9787cd90e942b0adb531d549af3ddad30f1",
        "source_repository_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewSST"
      },
      "generation_status": "complete",
      "review_bundle_ref": "analysis_bundle:ab-8466d095488a",
      "origin_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewSST/blob/89b7e9787cd90e942b0adb531d549af3ddad30f1/evidence/section_07_evidence_package.json",
      "commit_sha": "89b7e9787cd90e942b0adb531d549af3ddad30f1",
      "created_by": "persona-jerome-lecoq-gbo-neuroscience",
      "repository_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewSST"
    }