White Matter Network Architecture Guides Direct Electrical Stimulation Through Optimal State Transitions

TL;DR

This study uses network control theory and empirical data to show how white matter architecture influences the effectiveness of electrical brain stimulation in driving brain state transitions, especially for memory enhancement.

Contribution

It introduces a model-based approach linking white matter tracts to stimulation outcomes and validates it with combined ECoG and DWI data, advancing personalized brain stimulation strategies.

Findings

White matter tracts predict stimulation-induced state transitions more accurately than null models.

Optimal control predicts energy requirements based on initial and target brain states.

Structural properties influence stimulation efficiency and memory improvement potential.

Abstract

Electrical brain stimulation is currently being investigated as a therapy for neurological disease. However, opportunities to optimize such therapies are challenged by the fact that the beneficial impact of focal stimulation on both neighboring and distant regions is not well understood. Here, we use network control theory to build a model of brain network function that makes predictions about how stimulation spreads through the brain's white matter network and influences large-scale dynamics. We test these predictions using combined electrocorticography (ECoG) and diffusion weighted imaging (DWI) data who volunteered to participate in an extensive stimulation regimen. We posit a specific model-based manner in which white matter tracts constrain stimulation, defining its capacity to drive the brain to new states, including states associated with successful memory encoding. In a first validation of our model, we find that the true pattern of white matter tracts can be used to more accurately predict the state transitions induced by direct electrical stimulation than the artificial patterns of null models. We then use a targeted optimal control framework to solve for the optimal energy required to drive the brain to a given state. We show that, intuitively, our model predicts larger energy requirements when starting from states that are farther away from a target memory state. We then suggest testable hypotheses about which structural properties will lead to efficient stimulation for improving memory based on energy requirements. Our work demonstrates that individual white matter architecture plays a vital role in guiding the dynamics of direct electrical stimulation, more generally offering empirical support for the utility of network control theoretic models of brain response to stimulation.