Mathematical Analysis and Algorithms for Efficiently and Accurately Implementing Stochastic Simulations of Short-term Synaptic Depression and Facilitation

Overview

Journal Front Comput Neurosci

Specialty Biology

Date 2013 May 16

PMID 23675343

Citations 2

Authors

Mark D McDonnell

Ashutosh Mohan

Christian Stricker

Affiliations

Soon will be listed here.

Abstract

The release of neurotransmitter vesicles after arrival of a pre-synaptic action potential (AP) at cortical synapses is known to be a stochastic process, as is the availability of vesicles for release. These processes are known to also depend on the recent history of AP arrivals, and this can be described in terms of time-varying probabilities of vesicle release. Mathematical models of such synaptic dynamics frequently are based only on the mean number of vesicles released by each pre-synaptic AP, since if it is assumed there are sufficiently many vesicle sites, then variance is small. However, it has been shown recently that variance across sites can be significant for neuron and network dynamics, and this suggests the potential importance of studying short-term plasticity using simulations that do generate trial-to-trial variability. Therefore, in this paper we study several well-known conceptual models for stochastic availability and release. We state explicitly the random variables that these models describe and propose efficient algorithms for accurately implementing stochastic simulations of these random variables in software or hardware. Our results are complemented by mathematical analysis and statement of pseudo-code algorithms.

Citing Articles

Phase changes in neuronal postsynaptic spiking due to short term plasticity.

McDonnell M, Graham B PLoS Comput Biol. 2017; 13(9):e1005634.

PMID: 28937977 PMC: 5627952. DOI: 10.1371/journal.pcbi.1005634.

Modeling the influence of short term depression in vesicle release and stochastic calcium channel gating on auditory nerve spontaneous firing statistics.

Moezzi B, Iannella N, McDonnell M Front Comput Neurosci. 2015; 8:163.

PMID: 25566047 PMC: 4274967. DOI: 10.3389/fncom.2014.00163.

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