Abstract
The modulation of the sensitivity, or gain, of neural responses to input is an important component of neural computation. It has been shown that divisive gain modulation of neural responses can result from a stochastic shunting from balanced (mixed excitation and inhibition) background activity. This gain control scheme was developed and explored with static inputs, where the membrane and spike train statistics were stationary in time. However, input statistics, such as the firing rates of pre-synaptic neurons, are often dynamic, varying on timescales comparable to typical membrane time constants. Using a population density approach for integrate-and-fire neurons with dynamic and temporally rich inputs, we find that the same fluctuation-induced divisive gain modulation is operative for dynamic inputs driving nonequilibrium responses. Moreover, the degree of divisive scaling of the dynamic response is quantitatively the same as the steady-state responses—thus, gain modulation via balanced conductance fluctuations generalizes in a straight-forward way to a dynamic setting.
Highlights
Gain modulation is an adjustment of the inputoutput response of neurons, and is widely observed during neural processing [1]
We address the question of whether the fluctuation induced gain control mechanism explored for static transfer [11,16,23] can be operative for dynamic stimuli as well
Divisive gain modulation via increases of the background rates n0e and n0i occurs in the low firing rate region
Summary
Gain modulation (or gain control) is an adjustment of the inputoutput response of neurons, and is widely observed during neural processing [1]. Gain control mechanisms produce an invariance of receptive field properties [5] and orientation selectivity [6] to changes in overall stimulus contrast. Higher cognitive processes, such as attention, modulate the response gain of cells in primary visual cortex [7], as well as in V4 [8]. Despite the clear importance of gain control in a variety of neural computations, the biophysical mechanisms that support specific gain control mechanisms have been elusive [10,11,12,13,14,15,16,17,18,19,20]
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