- raw_fields
{
"n": 0,
"doi": "10.1152/jn.00401.2019",
"claim": "Divisive gain modulation by soma-targeting (PV-like) interneurons enables wider and faster frequency entrainment in neocortical microcircuits",
"evidence": "Extended Wilson-Cowan model with soma-targeting and dendrite-targeting interneuron subpopulations",
"effect_size": null,
"text_access": "fulltext",
"study_system": "neural mass model of neocortical microcircuit (extended Wilson-Cowan)",
"replication_status": "replication_unknown",
"claim_source_sentence": "Our results demonstrate that the presence of divisive inhibition in the microcircuit, as delivered by the soma-targeting interneurons, enables its entrainment to a wider range of input frequencies. Divisive inhibition also promotes a faster entrainment, with the microcircuit needing less time to converge to the fully entrained state.",
"replication_evidence_dois": [],
"effect_size_source_sentence": null
}- source_refs
[
"paper:paper-08ef4a26f5cf"
]
- source_span
Our results demonstrate that the presence of divisive inhibition in the microcircuit, as delivered by the soma-targeting interneurons, enables its entrainment to a wider range of input frequencies. Divisive inhibition also promotes a faster entrainment, with the microcircuit needing less time to converge to the fully entrained state.
- evidence_refs
[
{
"ref": "paper:paper-08ef4a26f5cf"
}
]- 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": "df9fc7e8d455b084152c9d713558dae0013cef21",
"source_repository_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewPV"
}