Abstract
Single neurons can dynamically change the gain of their spiking responses to take into account shifts in stimulus variance. Moreover, gain adaptation can occur across multiple timescales. Here, we examine the ability of a simple statistical model of spike trains, the generalized linear model (GLM), to account for these adaptive effects. The GLM describes spiking as a Poisson process whose rate depends on a linear combination of the stimulus and recent spike history. The GLM successfully replicates gain scaling observed in Hodgkin-Huxley simulations of cortical neurons that occurs when the ratio of spike-generating potassium and sodium conductances approaches one. Gain scaling in the GLM depends on the length and shape of the spike history filter. Additionally, the GLM captures adaptation that occurs over multiple timescales as a fractional derivative of the stimulus envelope, which has been observed in neurons that include long timescale afterhyperpolarization conductances. Fractional differentiation in GLMs requires long spike history that span several seconds. Together, these results demonstrate that the GLM provides a tractable statistical approach for examining single-neuron adaptive computations in response to changes in stimulus variance.
Highlights
Neurons adapt their spiking responses in a number of ways to the statistics of their inputs (Fairhall, 2014; Weber and Fairhall, 2019)
Applying the spike-triggered average (STA) analysis at the four stimulus standard deviation (SD), we quantified gain scaling in generalized linear model (GLM) fits and compared the gain scaling in the GLM simulations to the Hodgkin-Huxley style (HH) neurons (Figures 4B,C)
Across the range of spiking conductance values, we found that the GLM fits consistently showed gain scaling (Figure 4D)
Summary
Neurons adapt their spiking responses in a number of ways to the statistics of their inputs (Fairhall, 2014; Weber and Fairhall, 2019). Scaling of the gain by the stimulus standard deviation implies that single spikes maintain the same information about the stimulus independent of its overall amplitude. The mean firing rate can adapt to variations in the stimulus variance across multiple timescales (Fairhall et al, 2001b; Wark et al, 2007). This form of spike frequency adaptation can in some cases have power-law properties (Pozzorini et al, 2013) and serve to compute the fractional derivative of the variance (Anastasio, 1998; Lundstrom et al, 2008)
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