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"doi": "10.1523/jneurosci.1963-24.2025",
"claim": "Opioid Receptors Modulate Inhibition within the Prefrontal Cortex through Dissociable Cellular and Molecular Mechanisms.",
"title": null,
"cite_key": "Cole2025",
"evidence": "Opioid Receptors Modulate Inhibition within the Prefrontal Cortex through Dissociable Cellular and Molecular Mechanisms.. Aberrant signaling within cortical inhibitory microcircuits has been identified as a common signature of neuropsychiatric disorders. Interneuron (IN) activity is precisely regulated by neuromodulatory systems that evoke widespread changes in synaptic transmission and principal cell output. Cortical interneurons express high levels of opioid receptors, positioning opioid signaling as a critical regulator of inhibitory transmission; however, we lack a complete understanding o",
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"study_system": "cortex/HC",
"_source_cluster": "cluster_05_synaptic_connectivity",
"replication_status": "single",
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Opioid Receptors Modulate Inhibition within the Prefrontal Cortex through Dissociable Cellular and Molecular Mechanisms.. Aberrant signaling within cortical inhibitory microcircuits has been identified as a common signature of neuropsychiatric disorders. Interneuron (IN) activity is precisely regulated by neuromodulatory systems that evoke widespread changes in synaptic transmission and principal cell output. Cortical interneurons express high levels of opioid receptors, positioning opioid signaling as a critical regulator of inhibitory transmission; however, we lack a complete understanding o