BIOMAT Database Logo BIOMAT Database Logo

Diffusion approximation and first-passage-time problem for a model neuron. III. A birth-and-death process approach. 1988

V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Dipartimento di Informatica e Applicazioni, University of Salerno, Italy.

A stochastic model for single neuron's activity is constructed as the continuous limit of a birth-and-death process in the presence of a reversal hyperpolarization potential. The resulting process is a one dimensional diffusion with linear drift and infinitesimal variance, somewhat different from that proposed by Lánský and Lánská in a previous paper. A detailed study is performed for both the discrete process and its continuous approximation. In particular, the neuronal firing time problem is discussed and the moments of the firing time are explicitly obtained. Use of a new computation method is then made to obtain the firing p.d.f. The behaviour of mean, variance and coefficient of variation of the firing time and of its p.d.f. is analysed to pinpoint the role played by the parameters of the model. A mathematical description of the return process for this neuronal diffusion model is finally provided to obtain closed form expressions for the asymptotic moments and steady state p.d.f. of the neuron's membrane potential.

UI MeSH Term Description Entries
D008564 Membrane Potentials The voltage differences across a membrane. For cellular membranes they are computed by subtracting the voltage measured outside the membrane from the voltage measured inside the membrane. They result from differences of inside versus outside concentration of potassium, sodium, chloride, and other ions across cells' or ORGANELLES membranes. For excitable cells, the resting membrane potentials range between -30 and -100 millivolts. Physical, chemical, or electrical stimuli can make a membrane potential more negative (hyperpolarization), or less negative (depolarization). Resting Potentials,Transmembrane Potentials,Delta Psi,Resting Membrane Potential,Transmembrane Electrical Potential Difference,Transmembrane Potential Difference,Difference, Transmembrane Potential,Differences, Transmembrane Potential,Membrane Potential,Membrane Potential, Resting,Membrane Potentials, Resting,Potential Difference, Transmembrane,Potential Differences, Transmembrane,Potential, Membrane,Potential, Resting,Potential, Transmembrane,Potentials, Membrane,Potentials, Resting,Potentials, Transmembrane,Resting Membrane Potentials,Resting Potential,Transmembrane Potential,Transmembrane Potential Differences
D008959 Models, Neurological Theoretical representations that simulate the behavior or activity of the neurological system, processes or phenomena; includes the use of mathematical equations, computers, and other electronic equipment. Neurologic Models,Model, Neurological,Neurologic Model,Neurological Model,Neurological Models,Model, Neurologic,Models, Neurologic
D009431 Neural Conduction The propagation of the NERVE IMPULSE along the nerve away from the site of an excitation stimulus. Nerve Conduction,Conduction, Nerve,Conduction, Neural,Conductions, Nerve,Conductions, Neural,Nerve Conductions,Neural Conductions
D013269 Stochastic Processes Processes that incorporate some element of randomness, used particularly to refer to a time series of random variables. Process, Stochastic,Stochastic Process,Processes, Stochastic
D013997 Time Factors Elements of limited time intervals, contributing to particular results or situations. Time Series,Factor, Time,Time Factor

Related Publications

V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Diffusion approximation and first passage time problem for a model neuron.
June 1971, Kybernetik,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Anomalous diffusion and the first passage time problem
July 2000, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
First-passage-time problem for simulated stochastic diffusion processes.
March 1994, Computers in biology and medicine,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
First passage time problem for a drifted Ornstein-Uhlenbeck process.
June 2004, Mathematical biosciences,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Diffusion approximation for a multi-input model neuron.
November 1976, Biological cybernetics,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Modeling genome evolution with a diffusion approximation of a birth-and-death process.
November 2005, Bioinformatics (Oxford, England),
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
First-passage time for randomly flashing diffusion.
December 1995, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Mean first passage time for anomalous diffusion
November 2000, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
Water diffusion through a membrane protein channel: a first passage time approach.
August 2007, The Journal of chemical physics,
V Giorno, and P Lánský, and A G Nobile, and L M Ricciardi
First-passage-time distribution for diffusion through a planar wedge.
December 2008, Physical review. E, Statistical, nonlinear, and soft matter physics,
Copied contents to your clipboard!