Spike-frequency adaptation inhibits the pairwise spike correlation

Jixuan Wang; Bin Deng; Tianshi Gao; Jiang Wang; Hong Tan

doi:10.3389/fnins.2023.1193930

Spike-frequency adaptation inhibits the pairwise spike correlation

Front Neurosci. 2023 Jun 12:17:1193930. doi: 10.3389/fnins.2023.1193930. eCollection 2023.

Authors

Jixuan Wang¹, Bin Deng¹, Tianshi Gao¹, Jiang Wang¹, Hong Tan²

Affiliations

¹ School of Electrical and Information Engineering, Tianjin University, Tianjin, China.
² Department of Pathology, The Second Xiangya Hospital, Central South University, Changsha, Hunan, China.

Abstract

Introduction: The spike train output correlation with pairwise neurons determines the neural population coding, which depends on the average firing rate of individual neurons. Spike frequency adaptation (SFA), which serves as an essential cellular encoding strategy, modulates the firing rates of individual neurons. However, the mechanism by which the SFA modulates the output correlation of the spike trains remains unclear.

Methods: We introduce a pairwise neuron model that receives correlated inputs to generate spike trains, and the output correlation is qualified using Pearson correlation coefficient. The SFA is modeled using adaptation currents to examine its effect on the output correlation. Moreover, we use dynamic thresholds to explore the effect of SFA on output correlation. Furthermore, a simple phenomenological neuron model with a threshold-linear transfer function is utilized to confirm the effect of SFA on decreasing the output correlation.

Results: The results show that the adaptation currents decreased the output correlation by reducing the firing rate of a single neuron. At the onset of a correlated input, a transient process shows a decrease in interspike intervals (ISIs), resulting in a temporary increase in the correlation. When the adaptation current is sufficiently activated, the correlation reached a steady state, and the ISIs are maintained at higher values. The enhanced adaptation current achieved by increasing the adaptation conductance further reduces the pairwise correlation. While the time and slide windows influence the correlation, they make no difference in the effect of SFA on decreasing the output correlation. Moreover, SFA simulated by dynamic thresholds also decreases the output correlation. Furthermore, the simple phenomenological neuron model with a threshold-linear transfer function confirms the effect of SFA on decreasing the output correlation. The strength of the signal input and the slope of the linear component of the transfer function, the latter of which can be decreased by SFA, could together modulate the strength of the output correlation. Stronger SFA will decrease the slope and hence decrease the output correlation.

Conclusions: The results reveal that the SFA reduces the output correlation with pairwise neurons in the network by reducing the firing rate of individual neurons. This study provides a link between cellular non-linear mechanisms and network coding strategies.

Keywords: adaptation conductance; correlation; firing rate; pairwise neurons; single neuron; spike frequency adaptation.

Grants and funding

This study was supported by the National Natural Science Foundation of China under grant no. 62173241 and the Natural Science Foundation of Hunan Province in China under grant no. 2019JJ50857.