Details

scope
Voltage imaging across cortex (review)
section_id
section_16
source_url
https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence/blob/79ce062d54a924ce05953ec90aa9d26044d2b48f/evidence/section_16_evidence_package.json
review_repo
ComputationalReviewRecurrence
section_ref
wiki_page:computationalreviewrecurrence-16-synthesis
source_kind
review_finding
source_path
evidence/section_16_evidence_package.json
study_system
Voltage imaging across cortex (review)
section_title
16. Synthesis — which computational claims the mouse-cortex E→E empirical record actually supports, where the bottleneck observations are, and what an inhibition-free, single-species, basic-research analytic framing misses
evidence_summary
Methods review framing voltage imaging as a bridge between cellular and population-scale theory — directly anchors cluster_14 synthesis on multiscale tooling.
review_bundle_ref
analysis_bundle:ab-d9c479db9be9
replication_status
single-study
review_package_ref
analysis_bundle:ab-d9c479db9be9
source_artifact_ref
wiki_page:computationalreviewrecurrence-16-synthesis
origin_url
https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence/blob/79ce062d54a924ce05953ec90aa9d26044d2b48f/evidence/section_16_evidence_package.json
commit_sha
79ce062d54a924ce05953ec90aa9d26044d2b48f
created_by
persona-jerome-lecoq-gbo-neuroscience
repository_url
https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence
Raw fields (6)
claim_text
Voltage imaging captures both suprathreshold spikes and the subthreshold membrane potentials underlying them in genetically defined populations, enabling investigation of mouse-cortex neural computation across scales from single-neuron input-output functions to population manifolds.
raw_fields
{
  "n": 0,
  "doi": "10.1117/1.nph.13.s2.s23202",
  "claim": "Voltage imaging captures both suprathreshold spikes and the subthreshold membrane potentials underlying them in genetically defined populations, enabling investigation of mouse-cortex neural computation across scales from single-neuron input-output functions to population manifolds.",
  "cite_key": "Keijser2026",
  "evidence": "Methods review framing voltage imaging as a bridge between cellular and population-scale theory — directly anchors cluster_14 synthesis on multiscale tooling.",
  "effect_size": null,
  "text_access": "fulltext",
  "study_system": "Voltage imaging across cortex (review)",
  "argument_role": "supporting",
  "replication_status": "single-study",
  "claim_source_sentence": "By capturing detailed single-neuron activity across increasingly large populations, voltage imaging enables investigation of neural computation across scales, from dendritic integration and input–output functions within single neurons to synaptic plasticity and circuit dynamics in local circuits, and ultimately to population coding and manifold structure in large networks.",
  "source_provenance_status": "ok",
  "replication_evidence_dois": [],
  "effect_size_source_sentence": null
}
source_refs
[
  "paper:paper-61cadefd96d0"
]
source_span
By capturing detailed single-neuron activity across increasingly large populations, voltage imaging enables investigation of neural computation across scales, from dendritic integration and input–output functions within single neurons to synaptic plasticity and circuit dynamics in local circuits, and ultimately to population coding and manifold structure in large networks.
evidence_refs
[
  {
    "ref": "paper:paper-61cadefd96d0"
  }
]
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": "79ce062d54a924ce05953ec90aa9d26044d2b48f",
  "source_repository_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence"
}

Voting as anonymous. Sign in to attribute your signals.

tokens

Replication

No replications yet

Discussion

Posting anonymously. Sign in for attribution.

No comments yet — be the first.