AUTHOR=Mejias Jorge F., Payeur Alexandre , Selin Erik , Maler Leonard , Longtin Andre 

TITLE=Subtractive, divisive and non-monotonic gain control in feedforward nets linearized by noise and delays

JOURNAL=Frontiers in Computational Neuroscience

VOLUME=8

YEAR=2014

URL=https://www.frontiersin.org/journals/computational-neuroscience/articles/10.3389/fncom.2014.00019

DOI=10.3389/fncom.2014.00019

ISSN=1662-5188

ABSTRACT=<p>The control of input-to-output mappings, or gain control, is one of the main strategies used by neural networks for the processing and gating of information. Using a spiking neural network model, we studied the gain control induced by a form of inhibitory feedforward circuitry—also known as “open-loop feedback”—, which has been experimentally observed in a cerebellum-like structure in weakly electric fish. We found, both analytically and numerically, that this network displays three different regimes of gain control: subtractive, divisive, and non-monotonic. Subtractive gain control was obtained when noise is very low in the network. Also, it was possible to change from divisive to non-monotonic gain control by simply modulating the strength of the feedforward inhibition, which may be achieved via long-term synaptic plasticity. The particular case of divisive gain control has been previously observed <italic>in vivo</italic> in weakly electric fish. These gain control regimes were robust to the presence of temporal delays in the inhibitory feedforward pathway, which were found to linearize the input-to-output mappings (or f-I curves) via a novel variability-increasing mechanism. Our findings highlight the feedforward-induced gain control analyzed here as a highly versatile mechanism of information gating in the brain.</p>