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dc.contributor.authorNeymotin, Samuel A
dc.contributor.authorSuter, Benjamin A
dc.contributor.authorDura-Bernal, Salvador
dc.contributor.authorShepherd, Gordon M G
dc.contributor.authorMigliore, Michele
dc.contributor.authorLytton, William W
dc.date.accessioned2023-04-10T16:43:10Z
dc.date.available2023-04-10T16:43:10Z
dc.date.issued2016-10-19
dc.identifier.citationNeymotin SA, Suter BA, Dura-Bernal S, Shepherd GM, Migliore M, Lytton WW. Optimizing computer models of corticospinal neurons to replicate in vitro dynamics. J Neurophysiol. 2017 Jan 1;117(1):148-162. doi: 10.1152/jn.00570.2016. Epub 2016 Oct 19. PMID: 27760819; PMCID: PMC5209548.en_US
dc.identifier.eissn1522-1598
dc.identifier.doi10.1152/jn.00570.2016
dc.identifier.pmid27760819
dc.identifier.urihttp://hdl.handle.net/20.500.12648/8573
dc.description.abstractCorticospinal neurons (SPI), thick-tufted pyramidal neurons in motor cortex layer 5B that project caudally via the medullary pyramids, display distinct class-specific electrophysiological properties in vitro: strong sag with hyperpolarization, lack of adaptation, and a nearly linear frequency-current (F-I) relationship. We used our electrophysiological data to produce a pair of large archives of SPI neuron computer models in two model classes: 1) detailed models with full reconstruction; and 2) simplified models with six compartments. We used a PRAXIS and an evolutionary multiobjective optimization (EMO) in sequence to determine ion channel conductances. EMO selected good models from each of the two model classes to form the two model archives. Archived models showed tradeoffs across fitness functions. For example, parameters that produced excellent F-I fit produced a less-optimal fit for interspike voltage trajectory. Because of these tradeoffs, there was no single best model but rather models that would be best for particular usages for either single neuron or network explorations. Further exploration of exemplar models with strong F-I fit demonstrated that both the detailed and simple models produced excellent matches to the experimental data. Although dendritic ion identities and densities cannot yet be fully determined experimentally, we explored the consequences of a demonstrated proximal to distal density gradient of I, demonstrating that this would lead to a gradient of resonance properties with increased resonant frequencies more distally. We suggest that this dynamical feature could serve to make the cell particularly responsive to major frequency bands that differ by cortical layer.
dc.description.abstractWe developed models of motor cortex corticospinal neurons that replicate in vitro dynamics, including hyperpolarization-induced sag and realistic firing patterns. Models demonstrated resonance in response to synaptic stimulation, with resonance frequency increasing in apical dendrites with increasing distance from soma, matching the increasing oscillation frequencies spanning deep to superficial cortical layers. This gradient may enable specific corticospinal neuron dendrites to entrain to relevant oscillations in different cortical layers, contributing to appropriate motor output commands.
dc.language.isoenen_US
dc.relation.urlhttps://journals.physiology.org/doi/full/10.1152/jn.00570.2016en_US
dc.rightsCopyright © 2017 the American Physiological Society.
dc.rightsAttribution-NonCommercial-NoDerivatives 4.0 International*
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/*
dc.subjectHCN channelen_US
dc.subjectcomputer simulationen_US
dc.subjectcorticospinal neuronen_US
dc.subjecthyperpolarization-activated cyclic nucleotide-gated channelen_US
dc.subjectlayer 5en_US
dc.subjectmotor cortexen_US
dc.subjectneocortexen_US
dc.titleOptimizing computer models of corticospinal neurons to replicate in vitro dynamics.en_US
dc.typeArticle/Reviewen_US
dc.source.journaltitleJournal of neurophysiologyen_US
dc.source.volume117
dc.source.issue1
dc.source.beginpage148
dc.source.endpage162
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.source.countryUnited States
dc.description.versionVoRen_US
refterms.dateFOA2023-04-10T16:43:10Z
html.description.abstractCorticospinal neurons (SPI), thick-tufted pyramidal neurons in motor cortex layer 5B that project caudally via the medullary pyramids, display distinct class-specific electrophysiological properties in vitro: strong sag with hyperpolarization, lack of adaptation, and a nearly linear frequency-current (F-I) relationship. We used our electrophysiological data to produce a pair of large archives of SPI neuron computer models in two model classes: 1) detailed models with full reconstruction; and 2) simplified models with six compartments. We used a PRAXIS and an evolutionary multiobjective optimization (EMO) in sequence to determine ion channel conductances. EMO selected good models from each of the two model classes to form the two model archives. Archived models showed tradeoffs across fitness functions. For example, parameters that produced excellent F-I fit produced a less-optimal fit for interspike voltage trajectory. Because of these tradeoffs, there was no single best model but rather models that would be best for particular usages for either single neuron or network explorations. Further exploration of exemplar models with strong F-I fit demonstrated that both the detailed and simple models produced excellent matches to the experimental data. Although dendritic ion identities and densities cannot yet be fully determined experimentally, we explored the consequences of a demonstrated proximal to distal density gradient of I, demonstrating that this would lead to a gradient of resonance properties with increased resonant frequencies more distally. We suggest that this dynamical feature could serve to make the cell particularly responsive to major frequency bands that differ by cortical layer.
html.description.abstractWe developed models of motor cortex corticospinal neurons that replicate in vitro dynamics, including hyperpolarization-induced sag and realistic firing patterns. Models demonstrated resonance in response to synaptic stimulation, with resonance frequency increasing in apical dendrites with increasing distance from soma, matching the increasing oscillation frequencies spanning deep to superficial cortical layers. This gradient may enable specific corticospinal neuron dendrites to entrain to relevant oscillations in different cortical layers, contributing to appropriate motor output commands.
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.journalJournal of neurophysiology


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Copyright © 2017 the American Physiological Society.
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