Abstract
The auditory system processes temporal information at multiple scales, and disruptions to this temporal processing may lead to deficits in auditory tasks such as detecting and discriminating sounds in a noisy environment. Here, a modelling approach is used to study the temporal regularity of firing by chopper cells in the ventral cochlear nucleus, in both the normal and impaired auditory system. Chopper cells, which have a strikingly regular firing response, divide into two classes, sustained and transient, based on the time course of this regularity. Several hypotheses have been proposed to explain the behaviour of chopper cells, and the difference between sustained and transient cells in particular. However, there is no conclusive evidence so far. Here, a reduced mathematical model is developed and used to compare and test a wide range of hypotheses with a limited number of parameters. In line with recent work suggesting that there is no clear classification into discrete classes, simulations results show a continuum of cell types and behaviours: chopper-like behaviour arises for a wide range of parameters, suggesting that multiple mechanisms may underlie this behaviour. Finally, the model is used to predict the effects of a reduction in the number of auditory nerve fibres (deafferentation due to, for example, cochlear synaptopathy). We have made an online interactive version of this paper in which all the model parameters can be changed.
Highlights
A low parameter model reproduces chopper cell firing regularity
Multiple factors can account for sustained vs transient chopper cell response
The model explains stimulus level dependence of firing regularity
Chopper cells should fire more irregularly after deafferentation
An interactive version of the paper allows readers to change parameters