Data-driven inference for stationary jump-diffusion processes with application to membrane voltage fluctuations in pyramidal neurons.

Channel noise Chapman–Kolmogorov equation Electric fish Fokker–Planck equation Jump-diffusion processes Membrane noise Pyramidal neurons Stochastic differential equations

Journal

Journal of mathematical neuroscience

ISSN: 2190-8567

Titre abrégé: J Math Neurosci

Pays: Germany

ID NLM: 101572469

Informations de publication

Date de publication:
26 Jul 2019

Historique:

received: 07 09 2018

accepted: 09 07 2019

entrez: 28 7 2019

pubmed: 28 7 2019

medline: 28 7 2019

Statut: epublish

Résumé

The emergent activity of biological systems can often be represented as low-dimensional, Langevin-type stochastic differential equations. In certain systems, however, large and abrupt events occur and violate the assumptions of this approach. We address this situation here by providing a novel method that reconstructs a jump-diffusion stochastic process based solely on the statistics of the original data. Our method assumes that these data are stationary, that diffusive noise is additive, and that jumps are Poisson. We use threshold-crossing of the increments to detect jumps in the time series. This is followed by an iterative scheme that compensates for the presence of diffusive fluctuations that are falsely detected as jumps. Our approach is based on probabilistic calculations associated with these fluctuations and on the use of the Fokker-Planck and the differential Chapman-Kolmogorov equations. After some validation cases, we apply this method to recordings of membrane noise in pyramidal neurons of the electrosensory lateral line lobe of weakly electric fish. These recordings display large, jump-like depolarization events that occur at random times, the biophysics of which is unknown. We find that some pyramidal cells increase their jump rate and noise intensity as the membrane potential approaches spike threshold, while their drift function and jump amplitude distribution remain unchanged. As our method is fully data-driven, it provides a valuable means to further investigate the functional role of these jump-like events without relying on unconstrained biophysical models.

Identifiants

DOI: 10.1186/s13408-019-0074-3 PMID: 31350644 PMC: PMC6660545

pubmed: 31350644

doi: 10.1186/s13408-019-0074-3

pii: 10.1186/s13408-019-0074-3

pmc: PMC6660545

doi:

Types de publication

Journal Article

Langues

eng

Pagination

Subventions

Organisme : Natural Sciences and Engineering Research Council of Canada

ID : PGS-D3

Organisme : Natural Sciences and Engineering Research Council of Canada

ID : Discovery

Organisme : Ontario Government

ID : OGS

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