Attention for Causal Relationship Discovery from Biological Neural Dynamics
This work addresses causal relationship discovery in neuroscience, offering a proof-of-concept that is incremental but promising for future applications.
The paper tackles the problem of learning Granger causality in networks with complex nonlinear dynamics, such as neural systems, by using transformer models to forecast neuronal population dynamics, achieving accuracy equal to or better than popular Granger causality methods.
This paper explores the potential of the transformer models for learning Granger causality in networks with complex nonlinear dynamics at every node, as in neurobiological and biophysical networks. Our study primarily focuses on a proof-of-concept investigation based on simulated neural dynamics, for which the ground-truth causality is known through the underlying connectivity matrix. For transformer models trained to forecast neuronal population dynamics, we show that the cross attention module effectively captures the causal relationship among neurons, with an accuracy equal or superior to that for the most popular Granger causality analysis method. While we acknowledge that real-world neurobiology data will bring further challenges, including dynamic connectivity and unobserved variability, this research offers an encouraging preliminary glimpse into the utility of the transformer model for causal representation learning in neuroscience.