The Firing of an Excitable Neuron in the Presence of Stochastic Trains of Strong Synaptic Inputs

We consider a fast-slow excitable system subject to a stochastic excitatory input train and show that under general conditions, its long-term behavior is captured by an irreducible Markov chain with a limiting distribution. This limiting distribution allows for the analytical calculation of the syst...

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Veröffentlicht in:	Neural computation 2007-05, Vol.19 (5), p.1251-1294
Hauptverfasser:	Rubin, Jonathan, Josić, Krešimir
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Sprache:	eng
Schlagworte:	Action Potentials - physiology Animals Applied sciences Artificial intelligence Biological and medical sciences Cerebral Cortex - cytology Cerebral Cortex - physiology Computer science control theory systems Exact sciences and technology Fundamental and applied biological sciences. Psychology General aspects Learning and adaptive systems Likelihood Functions Markov analysis Mathematics Mathematics in biology. Statistical analysis. Models. Metrology. Data processing in biology (general aspects) Miscellaneous Models, Neurological Monte Carlo Method Monte Carlo simulation Neural Inhibition Neural Pathways Neurons Neurons - physiology Nonlinear Dynamics Numerical analysis Numerical analysis. Scientific computation Numerical methods in probability and statistics Parkinson's disease Periodicity Sciences and techniques of general use Stochastic models Stochastic Processes Synapses - physiology Synaptic Transmission - physiology Thalamus - cytology Thalamus - physiology Time Factors
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description	We consider a fast-slow excitable system subject to a stochastic excitatory input train and show that under general conditions, its long-term behavior is captured by an irreducible Markov chain with a limiting distribution. This limiting distribution allows for the analytical calculation of the system's probability of firing in response to each input, the expected number of response failures between firings, and the distribution of slow variable values between firings. Moreover, using this approach, it is possible to understand why the system will not have a stationary distribution and why Monte Carlo simulations do not converge under certain conditions. The analytical calculations involved can be performed whenever the distribution of interexcitation intervals and the recovery dynamics of the slow variable are known. The method can be extended to other models that feature a single variable that builds up to a threshold where an instantaneous spike and reset occur. We also discuss how the Markov chain analysis generalizes to any pair of input trains, excitatory or inhibitory and synaptic or not, such that the frequencies of the two trains are sufficiently different from each other. We illustrate this analysis on a model thalamocortical (TC) cell subject to two example distributions of excitatory synaptic inputs in the cases of constant and rhythmic inhibition. The analysis shows a drastic drop in the likelihood of firing just after inhibitory onset in the case of rhythmic inhibition, relative even to the case of elevated but constant inhibition. This observation provides support for a possible mechanism for the induction of motor symptoms in Parkinson's disease and for their relief by deep brain stimulation, analyzed in Rubin and Terman (2004).
doi_str_mv	10.1162/neco.2007.19.5.1251
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We illustrate this analysis on a model thalamocortical (TC) cell subject to two example distributions of excitatory synaptic inputs in the cases of constant and rhythmic inhibition. The analysis shows a drastic drop in the likelihood of firing just after inhibitory onset in the case of rhythmic inhibition, relative even to the case of elevated but constant inhibition. 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This limiting distribution allows for the analytical calculation of the system's probability of firing in response to each input, the expected number of response failures between firings, and the distribution of slow variable values between firings. Moreover, using this approach, it is possible to understand why the system will not have a stationary distribution and why Monte Carlo simulations do not converge under certain conditions. The analytical calculations involved can be performed whenever the distribution of interexcitation intervals and the recovery dynamics of the slow variable are known. The method can be extended to other models that feature a single variable that builds up to a threshold where an instantaneous spike and reset occur. We also discuss how the Markov chain analysis generalizes to any pair of input trains, excitatory or inhibitory and synaptic or not, such that the frequencies of the two trains are sufficiently different from each other. We illustrate this analysis on a model thalamocortical (TC) cell subject to two example distributions of excitatory synaptic inputs in the cases of constant and rhythmic inhibition. The analysis shows a drastic drop in the likelihood of firing just after inhibitory onset in the case of rhythmic inhibition, relative even to the case of elevated but constant inhibition. This observation provides support for a possible mechanism for the induction of motor symptoms in Parkinson's disease and for their relief by deep brain stimulation, analyzed in Rubin and Terman (2004).</description><subject>Action Potentials - physiology</subject><subject>Animals</subject><subject>Applied sciences</subject><subject>Artificial intelligence</subject><subject>Biological and medical sciences</subject><subject>Cerebral Cortex - cytology</subject><subject>Cerebral Cortex - physiology</subject><subject>Computer science; control theory; systems</subject><subject>Exact sciences and technology</subject><subject>Fundamental and applied biological sciences. Psychology</subject><subject>General aspects</subject><subject>Learning and adaptive systems</subject><subject>Likelihood Functions</subject><subject>Markov analysis</subject><subject>Mathematics</subject><subject>Mathematics in biology. Statistical analysis. Models. Metrology. Data processing in biology (general aspects)</subject><subject>Miscellaneous</subject><subject>Models, Neurological</subject><subject>Monte Carlo Method</subject><subject>Monte Carlo simulation</subject><subject>Neural Inhibition</subject><subject>Neural Pathways</subject><subject>Neurons</subject><subject>Neurons - physiology</subject><subject>Nonlinear Dynamics</subject><subject>Numerical analysis</subject><subject>Numerical analysis. Scientific computation</subject><subject>Numerical methods in probability and statistics</subject><subject>Parkinson's disease</subject><subject>Periodicity</subject><subject>Sciences and techniques of general use</subject><subject>Stochastic models</subject><subject>Stochastic Processes</subject><subject>Synapses - physiology</subject><subject>Synaptic Transmission - physiology</subject><subject>Thalamus - cytology</subject><subject>Thalamus - physiology</subject><subject>Time Factors</subject><issn>0899-7667</issn><issn>1530-888X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2007</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkV9r1TAYxoMo7mz6CQQpwrxrlzd_m0sZ2xyMOdgRvItpmm4ZPWlNWnF--qWcA5Oh7iqQ_N7ned48CL0DXAEIchScHSqCsaxAVbwCwuEFWgGnuKzr-ttLtMK1UqUUQu6h_ZTuMMYCMH-N9kDSGogQK_R9feuKUx99uCmGrjChOPll_WSa3hWXbo5DKHwopgxdRZdcsG7BrqfB3po0eVuso_EhbS8zfVNc3wczLi_nYZyn9Aa96kyf3NvdeYC-np6sjz-XF1_Ozo8_XZSWKT6VvGmopI62tTUNM4J1ylpOOOPgSOc6alUrTKeYUxYYJx2xUirathaLxkqgB-jjVneMw4_ZpUlvfLKu701ww5y0xBQzVYtnQVCCSQIsgx-egHfDHENeQhPIv4cxkxmiW8jGIaXoOj1GvzHxXgPWS016qUkvNWVlzfVSU556v5Oem41rH2d2vWTgcAeYZE3fRROsT49cLQEDLPZnW27j_4i3WP4E5bmmmDCqsj2BnEbjWv_24z8iHf1F6X9LPADUcsBe</recordid><startdate>20070501</startdate><enddate>20070501</enddate><creator>Rubin, Jonathan</creator><creator>Josić, Krešimir</creator><general>MIT Press</general><general>MIT Press Journals, The</general><scope>IQODW</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SC</scope><scope>8FD</scope><scope>JQ2</scope><scope>L7M</scope><scope>L~C</scope><scope>L~D</scope><scope>7TK</scope><scope>7X8</scope></search><sort><creationdate>20070501</creationdate><title>The Firing of an Excitable Neuron in the Presence of Stochastic Trains of Strong Synaptic Inputs</title><author>Rubin, Jonathan ; Josić, Krešimir</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c495t-5bb373e3d8cab4a64f9cc525451e2fef3c9d6af94e9c1452f2c7793ddc06bc713</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2007</creationdate><topic>Action Potentials - physiology</topic><topic>Animals</topic><topic>Applied sciences</topic><topic>Artificial intelligence</topic><topic>Biological and medical sciences</topic><topic>Cerebral Cortex - cytology</topic><topic>Cerebral Cortex - physiology</topic><topic>Computer science; control theory; systems</topic><topic>Exact sciences and technology</topic><topic>Fundamental and applied biological sciences. Psychology</topic><topic>General aspects</topic><topic>Learning and adaptive systems</topic><topic>Likelihood Functions</topic><topic>Markov analysis</topic><topic>Mathematics</topic><topic>Mathematics in biology. Statistical analysis. Models. Metrology. Data processing in biology (general aspects)</topic><topic>Miscellaneous</topic><topic>Models, Neurological</topic><topic>Monte Carlo Method</topic><topic>Monte Carlo simulation</topic><topic>Neural Inhibition</topic><topic>Neural Pathways</topic><topic>Neurons</topic><topic>Neurons - physiology</topic><topic>Nonlinear Dynamics</topic><topic>Numerical analysis</topic><topic>Numerical analysis. Scientific computation</topic><topic>Numerical methods in probability and statistics</topic><topic>Parkinson's disease</topic><topic>Periodicity</topic><topic>Sciences and techniques of general use</topic><topic>Stochastic models</topic><topic>Stochastic Processes</topic><topic>Synapses - physiology</topic><topic>Synaptic Transmission - physiology</topic><topic>Thalamus - cytology</topic><topic>Thalamus - physiology</topic><topic>Time Factors</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Rubin, Jonathan</creatorcontrib><creatorcontrib>Josić, Krešimir</creatorcontrib><collection>Pascal-Francis</collection><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Computer and Information Systems Abstracts</collection><collection>Technology Research Database</collection><collection>ProQuest Computer Science Collection</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>Computer and Information Systems Abstracts Academic</collection><collection>Computer and Information Systems Abstracts Professional</collection><collection>Neurosciences Abstracts</collection><collection>MEDLINE - Academic</collection><jtitle>Neural computation</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Rubin, Jonathan</au><au>Josić, Krešimir</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>The Firing of an Excitable Neuron in the Presence of Stochastic Trains of Strong Synaptic Inputs</atitle><jtitle>Neural computation</jtitle><addtitle>Neural Comput</addtitle><date>2007-05-01</date><risdate>2007</risdate><volume>19</volume><issue>5</issue><spage>1251</spage><epage>1294</epage><pages>1251-1294</pages><issn>0899-7667</issn><eissn>1530-888X</eissn><coden>NEUCEB</coden><abstract>We consider a fast-slow excitable system subject to a stochastic excitatory input train and show that under general conditions, its long-term behavior is captured by an irreducible Markov chain with a limiting distribution. 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We illustrate this analysis on a model thalamocortical (TC) cell subject to two example distributions of excitatory synaptic inputs in the cases of constant and rhythmic inhibition. The analysis shows a drastic drop in the likelihood of firing just after inhibitory onset in the case of rhythmic inhibition, relative even to the case of elevated but constant inhibition. This observation provides support for a possible mechanism for the induction of motor symptoms in Parkinson's disease and for their relief by deep brain stimulation, analyzed in Rubin and Terman (2004).</abstract><cop>One Rogers Street, Cambridge, MA 02142-1209, USA</cop><pub>MIT Press</pub><pmid>17381266</pmid><doi>10.1162/neco.2007.19.5.1251</doi><tpages>44</tpages></addata></record>
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subjects	Action Potentials - physiology Animals Applied sciences Artificial intelligence Biological and medical sciences Cerebral Cortex - cytology Cerebral Cortex - physiology Computer science control theory systems Exact sciences and technology Fundamental and applied biological sciences. Psychology General aspects Learning and adaptive systems Likelihood Functions Markov analysis Mathematics Mathematics in biology. Statistical analysis. Models. Metrology. Data processing in biology (general aspects) Miscellaneous Models, Neurological Monte Carlo Method Monte Carlo simulation Neural Inhibition Neural Pathways Neurons Neurons - physiology Nonlinear Dynamics Numerical analysis Numerical analysis. Scientific computation Numerical methods in probability and statistics Parkinson's disease Periodicity Sciences and techniques of general use Stochastic models Stochastic Processes Synapses - physiology Synaptic Transmission - physiology Thalamus - cytology Thalamus - physiology Time Factors
title	The Firing of an Excitable Neuron in the Presence of Stochastic Trains of Strong Synaptic Inputs
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