Details

scope
vip-interneurons
claim_text
The proportion of VIP interneurons increases from primary sensory to executive (frontal/motor) cortex, while PV proportions decrease, suggesting region-specific inhibitory rebalancing along the cortical hierarchy.
section_id
section_09
source_url
https://github.com/AllenNeuralDynamics/ComputationalReviewVIP/blob/95e761177f7d2ec565983d3307c14ec238f9677c/evidence/section_09_evidence_package.json
review_repo
ComputationalReviewVIP
section_ref
wiki_page:computationalreviewvip-09-cross-areas
source_kind
review_finding
source_path
evidence/section_09_evidence_package.json
section_title
VIP Interneurons Across Brain Regions
review_bundle_ref
analysis_bundle:ab-2ce40c33e827
replication_status
unevaluated
review_package_ref
analysis_bundle:ab-2ce40c33e827
source_artifact_ref
wiki_page:computationalreviewvip-09-cross-areas
origin_url
https://github.com/AllenNeuralDynamics/ComputationalReviewVIP/blob/95e761177f7d2ec565983d3307c14ec238f9677c/evidence/section_09_evidence_package.json
commit_sha
95e761177f7d2ec565983d3307c14ec238f9677c
created_by
persona-jerome-lecoq-gbo-neuroscience
repository_url
https://github.com/AllenNeuralDynamics/ComputationalReviewVIP
Raw fields (5)
raw_fields
{
  "n": null,
  "doi": "10.1093/cercor/bhaa056",
  "year": "2020",
  "claim": "The proportion of VIP interneurons increases from primary sensory to executive (frontal/motor) cortex, while PV proportions decrease, suggesting region-specific inhibitory rebalancing along the cortical hierarchy.",
  "title": null,
  "region": "cortex (sensory→executive)",
  "cite_key": "Torresgomez2020",
  "effect_size": null,
  "text_access": "abstract_only",
  "conflict_flag": false,
  "fig_table_ref": "Fig.2",
  "_source_cluster": "cluster_08_brain_regions",
  "evidence_gap_flag": false,
  "unreplicated_flag": false,
  "replication_status": null,
  "_source_cluster_index": 35,
  "claim_source_sentence": "Neuronal spiking activity encoding working memory (WM) is robust in primate association cortices but weak or absent in early sensory cortices. This may be linked to changes in the proportion of neuronal types across areas that influence circuits' ability to generate recurrent excitation. We recorded neuronal activity from areas middle temporal (MT), medial superior temporal (MST), and the lateral "
}
source_refs
[
  "paper:paper-e20ad76ed156"
]
source_span
Neuronal spiking activity encoding working memory (WM) is robust in primate association cortices but weak or absent in early sensory cortices. This may be linked to changes in the proportion of neuronal types across areas that influence circuits' ability to generate recurrent excitation. We recorded neuronal activity from areas middle temporal (MT), medial superior temporal (MST), and the lateral
evidence_refs
[
  {
    "ref": "paper:paper-e20ad76ed156"
  }
]
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": "95e761177f7d2ec565983d3307c14ec238f9677c",
  "source_repository_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewVIP"
}

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