Stable Control of Firing Rate Mean and Variance by Dual Homeostatic Mechanisms
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- 作者:Jonathan Cannon ; Paul Miller
- 关键词:Homeostasis ; Dynamical systems ; Stability ; Integrator ; Synaptic scaling ; Averaging
- 刊名:The Journal of Mathematical Neuroscience
- 出版年:2017
- 出版时间:December 2017
- 年:2017
- 卷:7
- 期:1
- 全文大小:2864KB
- 刊物主题:Mathematical Modeling and Industrial Mathematics; Neurosciences; Applications of Mathematics;
- 出版者:Springer Berlin Heidelberg
- ISSN:2190-8567
- 卷排序:7
文摘
Homeostatic processes that provide negative feedback to regulate neuronal firing rates are essential for normal brain function. Indeed, multiple parameters of individual neurons, including the scale of afferent synapse strengths and the densities of specific ion channels, have been observed to change on homeostatic time scales to oppose the effects of chronic changes in synaptic input. This raises the question of whether these processes are controlled by a single slow feedback variable or multiple slow variables. A single homeostatic process providing negative feedback to a neuron’s firing rate naturally maintains a stable homeostatic equilibrium with a characteristic mean firing rate; but the conditions under which multiple slow feedbacks produce a stable homeostatic equilibrium have not yet been explored. Here we study a highly general model of homeostatic firing rate control in which two slow variables provide negative feedback to drive a firing rate toward two different target rates. Using dynamical systems techniques, we show that such a control system can be used to stably maintain a neuron’s characteristic firing rate mean and variance in the face of perturbations, and we derive conditions under which this happens. We also derive expressions that clarify the relationship between the homeostatic firing rate targets and the resulting stable firing rate mean and variance. We provide specific examples of neuronal systems that can be effectively regulated by dual homeostasis. One of these examples is a recurrent excitatory network, which a dual feedback system can robustly tune to serve as an integrator.