English

NeuroSSM: Multiscale Differential State-Space Modeling for Context-Aware fMRI Analysis

Signal Processing 2026-01-06 v1 Machine Learning

Abstract

Accurate fMRI analysis requires sensitivity to temporal structure across multiple scales, as BOLD signals encode cognitive processes that emerge from fast transient dynamics to slower, large-scale fluctuations. Existing deep learning (DL) approaches to temporal modeling face challenges in jointly capturing these dynamics over long fMRI time series. Among current DL models, transformers address long-range dependencies by explicitly modeling pairwise interactions through attention, but the associated quadratic computational cost limits effective integration of temporal dependencies across long fMRI sequences. Selective state-space models (SSMs) instead model long-range temporal dependencies implicitly through latent state evolution in a dynamical system, enabling efficient propagation of dependencies over time. However, recent SSM-based approaches for fMRI commonly operate on derived functional connectivity representations and employ single-scale temporal processing. These design choices constrain the ability to jointly represent fast transient dynamics and slower global trends within a single model. We propose NeuroSSM, a selective state-space architecture designed for end-to-end analysis of raw BOLD signals in fMRI time series. NeuroSSM addresses the above limitations through two complementary design components: a multiscale state-space backbone that captures fast and slow dynamics concurrently, and a parallel differencing branch that increases sensitivity to transient state changes. Experiments on clinical and non-clinical datasets demonstrate that NeuroSSM achieves competitive performance and efficiency against state-of-the-art fMRI analysis methods.

Keywords

Cite

@article{arxiv.2601.01229,
  title  = {NeuroSSM: Multiscale Differential State-Space Modeling for Context-Aware fMRI Analysis},
  author = {Furkan Genç and Boran İsmet Macun and Sait Sarper Özaslan and Emine U. Saritas and Tolga Çukur},
  journal= {arXiv preprint arXiv:2601.01229},
  year   = {2026}
}
R2 v1 2026-07-01T08:49:25.512Z