English

Modelling ion channels with a view towards identifiability

Biomolecules 2025-10-31 v1

Abstract

Aggregated Markov models provide a flexible framework for stochastic dynamics that develops on multiple timescales. For example, Markov models for ion channels often consist of multiple open and closed state to account for "slow" and "fast" openings and closings of the channel. The approach is a popular tool in the construction of mechanistic models of ion channels - instead of viewing model states as generators of sojourn times of a certain characteristic length, each individual model state is interpreted as a representation of a distinct biophysical state. We will review the properties of aggregated Markov models and discuss the implications for mechanistic modelling. First, we show how the aggregated Markov models with a given number of states can be calculated using P\'olya enumeration However, models with nOn_O open and nCn_C closed states that exceed the maximum number 2nOnC2 n_O n_C of parameters are non-identifiable. We will present two derivations for this classical result and investigate non-identifiability further via a detailed analysis of the non-identifiable fully connected three-state model. Finally, we will discuss the implications of non-identifiability for mechanistic modelling of ion channels. We will argue that instead of designing models based on assumed transitions between distinct biophysical states which are modulated by ligand binding, it is preferable to build models based on additional sources of data that give more direct insight into the dynamics of conformational changes.

Keywords

Cite

@article{arxiv.2510.26728,
  title  = {Modelling ion channels with a view towards identifiability},
  author = {Ivo Siekmann},
  journal= {arXiv preprint arXiv:2510.26728},
  year   = {2025}
}

Comments

37 pages, 6 figures, presented at MATRIX workshop "Parameter Identifiability in Mathematical Biology" https://www.matrix-inst.org.au/events/parameter-identifiability-in-mathematical-biology/?

R2 v1 2026-07-01T07:14:15.360Z