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- Live5/17/2026, 4:35:28 PM
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{ "scope": "mouse; V1, visual cortex; whole-cell patch, optogenetics; Current biology : CB", "claim_text": "Here, we sought to determine whether higher order visual cortical areas lateromedial (LM), anterolateral (AL), posteromedial (PM), and anteromedial (AM) have specialized anatomical and physiological…", "raw_fields": { "n": null, "doi": "10.1016/j.cub.2021.09.042", "claim": "Here, we sought to determine whether higher order visual cortical areas lateromedial (LM), anterolateral (AL), posteromedial (PM), and anteromedial (AM) have specialized anatomical and physiological…", "cite_key": "Li2021a", "evidence": "Cortical visual processing transforms features of the external world into increasingly complex and specialized neuronal representations. These transformations arise in part through target-specific routing of information; however, within-area computations may also contribute to area-specific function. Here, we sought to determine whether higher order visual cortical areas lateromedial (LM), anterolateral (AL), posteromedial (PM), and anteromedial (AM) have specialized anatomical and physiological...", "effect_size": "In addition, we find that despite a lack of an overall difference in PV cell density across areas, there are some significant differences when separating by layers: PV cells in L6 are significantly more dense in AM compared to LM and AL, and PV cells in L5 are significantly denser in LM and AL versus AM (PV: one-way ANOVA with post hoc Tukey tests; L5 p=0.049, LM vs PM p=0.044; L6 p=0.008; LM vs PM p=0.011, AL vs PM p=0.037; n=8 mice).", "text_access": "fulltext", "study_system": "mouse; V1, visual cortex; whole-cell patch, optogenetics; Current biology : CB", "argument_role": "supporting", "replication_status": "single_study", "claim_source_sentence": "Here, we sought to determine whether higher order visual cortical areas lateromedial (LM), anterolateral (AL), posteromedial (PM), and anteromedial (AM) have specialized anatomical and physiological properties by using a combination of whole-cell recordings and optogenetic stimulation of primary visual cortex (V1) axons in vitro.", "source_provenance_status": "ok", "replication_evidence_dois": [], "claim_rewritten_from_source": true, "effect_size_source_sentence": "In addition, we find that despite a lack of an overall difference in PV cell density across areas, there are some significant differences when separating by layers: PV cells in L6 are significantly more dense in AM compared to LM and AL, and PV cells in L5 are significantly denser in LM and AL versus AM (PV: one-way ANOVA with post hoc Tukey tests; L5 p=0.049, LM vs PM p=0.044; L6 p=0.008; LM vs PM p=0.011, AL vs PM p=0.037; n=8 mice)." }, "section_id": "section_09", "source_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence/blob/79ce062d54a924ce05953ec90aa9d26044d2b48f/evidence/section_09_evidence_package.json", "effect_size": "In addition, we find that despite a lack of an overall difference in PV cell density across areas, there are some significant differences when separating by layers: PV cells in L6 are significantly more dense in AM compared to LM and AL, and PV cells in L5 are significantly denser in LM and AL versus AM (PV: one-way ANOVA with post hoc Tukey tests; L5 p=0.049, LM vs PM p=0.044; L6 p=0.008; LM vs PM p=0.011, AL vs PM p=0.037; n=8 mice).", "review_repo": "ComputationalReviewRecurrence", "section_ref": "wiki_page:computationalreviewrecurrence-09-amplification-isn", "source_kind": "review_finding", "source_path": "evidence/section_09_evidence_package.json", "source_refs": [ "paper:paper-21937e5a070f" ], "source_span": "Here, we sought to determine whether higher order visual cortical areas lateromedial (LM), anterolateral (AL), posteromedial (PM), and anteromedial (AM) have specialized anatomical and physiological properties by using a combination of whole-cell recordings and optogenetic stimulation of primary visual cortex (V1) axons in vitro.", "study_system": "mouse; V1, visual cortex; whole-cell patch, optogenetics; Current biology : CB", "evidence_refs": [ { "ref": "paper:paper-21937e5a070f" } ], "section_title": "9. Physiological signature I — recurrent amplification of weak inputs in mouse cortex; balanced-amplification regimes; ISN operation", "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" }, "evidence_summary": "Cortical visual processing transforms features of the external world into increasingly complex and specialized neuronal representations. These transformations arise in part through target-specific routing of information; however, within-area computations may also contribute to area-specific function. Here, we sought to determine whether higher order visual cortical areas lateromedial (LM), anterolateral (AL), posteromedial (PM), and anteromedial (AM) have specialized anatomical and physiological...", "review_bundle_ref": "analysis_bundle:ab-d9c479db9be9", "replication_status": "single_study", "review_package_ref": "analysis_bundle:ab-d9c479db9be9", "source_artifact_ref": "wiki_page:computationalreviewrecurrence-09-amplification-isn", "origin_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence/blob/79ce062d54a924ce05953ec90aa9d26044d2b48f/evidence/section_09_evidence_package.json", "commit_sha": "79ce062d54a924ce05953ec90aa9d26044d2b48f", "created_by": "persona-jerome-lecoq-gbo-neuroscience", "repository_url": "https://github.com/AllenNeuralDynamics/ComputationalReviewRecurrence" }