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dc.contributor.authorBorges, Fernando S
dc.contributor.authorMoreira, Joao V S
dc.contributor.authorTakarabe, Lavinia M
dc.contributor.authorLytton, William W
dc.contributor.authorDura-Bernal, Salvador
dc.date.accessioned2023-04-10T15:30:29Z
dc.date.available2023-04-10T15:30:29Z
dc.date.issued2022-09-22
dc.identifier.citationBorges FS, Moreira JVS, Takarabe LM, Lytton WW, Dura-Bernal S. Large-scale biophysically detailed model of somatosensory thalamocortical circuits in NetPyNE. Front Neuroinform. 2022 Sep 22;16:884245. doi: 10.3389/fninf.2022.884245. PMID: 36213546; PMCID: PMC9536213.en_US
dc.identifier.issn1662-5196
dc.identifier.doi10.3389/fninf.2022.884245
dc.identifier.pmid36213546
dc.identifier.urihttp://hdl.handle.net/20.500.12648/8556
dc.description.abstractThe primary somatosensory cortex (S1) of mammals is critically important in the perception of touch and related sensorimotor behaviors. In 2015, the Blue Brain Project (BBP) developed a groundbreaking rat S1 microcircuit simulation with over 31,000 neurons with 207 morpho-electrical neuron types, and 37 million synapses, incorporating anatomical and physiological information from a wide range of experimental studies. We have implemented this highly detailed and complex S1 model in NetPyNE, using the data available in the Neocortical Microcircuit Collaboration Portal. NetPyNE provides a Python high-level interface to NEURON and allows defining complicated multiscale models using an intuitive declarative standardized language. It also facilitates running parallel simulations, automates the optimization and exploration of parameters using supercomputers, and provides a wide range of built-in analysis functions. This will make the S1 model more accessible and simpler to scale, modify and extend in order to explore research questions or interconnect to other existing models. Despite some implementation differences, the NetPyNE model preserved the original cell morphologies, electrophysiological responses and spatial distribution for all 207 cell types; and the connectivity properties of all 1941 pathways, including synaptic dynamics and short-term plasticity (STP). The NetPyNE S1 simulations produced reasonable physiological firing rates and activity patterns across all populations. When STP was included, the network generated a 1 Hz oscillation comparable to the original model -like state. By then reducing the extracellular calcium concentration, the model reproduced the original S1 -like states with asynchronous activity. These results validate the original study using a new modeling tool. Simulated local field potentials (LFPs) exhibited realistic oscillatory patterns and features, including distance- and frequency-dependent attenuation. The model was extended by adding thalamic circuits, including 6 distinct thalamic populations with intrathalamic, thalamocortical (TC) and corticothalamic connectivity derived from experimental data. The thalamic model reproduced single known cell and circuit-level dynamics, including burst and tonic firing modes and oscillatory patterns, providing a more realistic input to cortex and enabling study of TC interactions. Overall, our work provides a widely accessible, data-driven and biophysically-detailed model of the somatosensory TC circuits that can be employed as a community tool for researchers to study neural dynamics, function and disease.
dc.language.isoenen_US
dc.relation.urlhttps://www.frontiersin.org/articles/10.3389/fninf.2022.884245/fullen_US
dc.rightsCopyright © 2022 Borges, Moreira, Takarabe, Lytton and Dura-Bernal.
dc.rightsAttribution-NonCommercial-NoDerivatives 4.0 International*
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/*
dc.subjectbiophysicalen_US
dc.subjectcorticalen_US
dc.subjectlarge-scale modelen_US
dc.subjectmultiscaleen_US
dc.subjectsomatosensory cortexen_US
dc.subjectthalamocortical circuitsen_US
dc.titleLarge-scale biophysically detailed model of somatosensory thalamocortical circuits in NetPyNE.en_US
dc.typeArticle/Reviewen_US
dc.source.journaltitleFrontiers in neuroinformaticsen_US
dc.source.volume16
dc.source.beginpage884245
dc.source.endpage
dc.source.countrySwitzerland
dc.description.versionVoRen_US
refterms.dateFOA2023-04-10T15:30:29Z
html.description.abstractThe primary somatosensory cortex (S1) of mammals is critically important in the perception of touch and related sensorimotor behaviors. In 2015, the Blue Brain Project (BBP) developed a groundbreaking rat S1 microcircuit simulation with over 31,000 neurons with 207 morpho-electrical neuron types, and 37 million synapses, incorporating anatomical and physiological information from a wide range of experimental studies. We have implemented this highly detailed and complex S1 model in NetPyNE, using the data available in the Neocortical Microcircuit Collaboration Portal. NetPyNE provides a Python high-level interface to NEURON and allows defining complicated multiscale models using an intuitive declarative standardized language. It also facilitates running parallel simulations, automates the optimization and exploration of parameters using supercomputers, and provides a wide range of built-in analysis functions. This will make the S1 model more accessible and simpler to scale, modify and extend in order to explore research questions or interconnect to other existing models. Despite some implementation differences, the NetPyNE model preserved the original cell morphologies, electrophysiological responses and spatial distribution for all 207 cell types; and the connectivity properties of all 1941 pathways, including synaptic dynamics and short-term plasticity (STP). The NetPyNE S1 simulations produced reasonable physiological firing rates and activity patterns across all populations. When STP was included, the network generated a 1 Hz oscillation comparable to the original model -like state. By then reducing the extracellular calcium concentration, the model reproduced the original S1 -like states with asynchronous activity. These results validate the original study using a new modeling tool. Simulated local field potentials (LFPs) exhibited realistic oscillatory patterns and features, including distance- and frequency-dependent attenuation. The model was extended by adding thalamic circuits, including 6 distinct thalamic populations with intrathalamic, thalamocortical (TC) and corticothalamic connectivity derived from experimental data. The thalamic model reproduced single known cell and circuit-level dynamics, including burst and tonic firing modes and oscillatory patterns, providing a more realistic input to cortex and enabling study of TC interactions. Overall, our work provides a widely accessible, data-driven and biophysically-detailed model of the somatosensory TC circuits that can be employed as a community tool for researchers to study neural dynamics, function and disease.
dc.description.institutionSUNY Downstateen_US
dc.description.departmentPhysiology and Pharmacologyen_US
dc.description.departmentNathan Kline Institute for Psychiatric Researchen_US
dc.description.degreelevelN/Aen_US
dc.identifier.journalFrontiers in neuroinformatics


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Copyright © 2022 Borges, Moreira, Takarabe, Lytton and Dura-Bernal.
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