Coupled Transformer Autoencoder for Disentangling Multi-Region Neural Latent Dynamics

Sristi, Ram Dyuthi; Gilja, Vikash; Narasimha, Sowmya Manojna; Musall, Simon; Despatin, Alice; Mishne, Gal; Huang, Jingya

doi:10.48550/arXiv.2510.20068

Preprint

FZJ-2025-05869

Coupled Transformer Autoencoder for Disentangling Multi-Region Neural Latent Dynamics

Sristi, R. D. ; Narasimha, S. M. ; Huang, J. ; Despatin, A. ; Musall, S.FZJ* ; Gilja, V. ; Mishne, G.

2025
arXiv

arXiv (2025) [10.48550/arXiv.2510.20068]

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Please use a persistent id in citations: doi:10.48550/arXiv.2510.20068 doi:10.34734/FZJ-2025-05869

Abstract: Simultaneous recordings from thousands of neurons across multiple brain areas reveal rich mixtures of activity that are shared between regions and dynamics that are unique to each region. Existing alignment or multi-view methods neglect temporal structure, whereas dynamical latent variable models capture temporal dependencies but are usually restricted to a single area, assume linear read-outs, or conflate shared and private signals. We introduce the Coupled Transformer Autoencoder (CTAE) - a sequence model that addresses both (i) non-stationary, non-linear dynamics and (ii) separation of shared versus region-specific structure in a single framework. CTAE employs transformer encoders and decoders to capture long-range neural dynamics and explicitly partitions each region's latent space into orthogonal shared and private subspaces. We demonstrate the effectiveness of CTAE on two high-density electrophysiology datasets with simultaneous recordings from multiple regions, one from motor cortical areas and the other from sensory areas. CTAE extracts meaningful representations that better decode behavioral variables compared to existing approaches.

Keyword(s): Machine Learning (cs.LG) ; FOS: Computer and information sciences

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