The explanatory power of activity flow models of brain function

TL;DR

This paper reviews how activity flow models, which integrate brain connectivity and task-evoked activity, can provide mechanistic explanations of neurocognitive functions and have potential for advancing neuroscience and clinical treatments.

Contribution

It highlights the integration of connectivity and activity data into activity flow models as a promising approach for mechanistic understanding of brain function.

Findings

Activity flow models can simulate task-evoked brain activations.

These models offer explanations based on causal principles and empirical data.

Potential applications include developing clinical treatments for brain disorders.

Abstract

Tremendous neuroscientific progress has recently been made by mapping brain connectivity, complementing extensive knowledge of task-evoked brain activation patterns. However, despite evidence that they are related, these connectivity and activity lines of research have mostly progressed separately. Here I review the notable productivity and future promise of combining connectivity and task-evoked activity estimates into activity flow models. These data-driven computational models simulate the generation of task-evoked activations (including those linked to behavior), producing empirically-supported explanations of the origin of neurocognitive functions based on the flow of task-evoked activity over empirical brain connections. Critically, by incorporating causal principles and extensive empirical constraints from brain data, this approach can provide more mechanistic accounts of neurocognitive phenomena than purely predictive (as opposed to explanatory) models or models optimized primarily for task performance (e.g., standard artificial neural networks). The variety of activity-flow-based explanations reported so far are covered here along with important methodological and theoretical considerations when discovering new activity-flow-based explanations. Together, these considerations illustrate the promise of activity flow modeling for the future of neuroscience and ultimately for the development of novel clinical treatments (e.g., using brain stimulation) for brain disorders.