Abstract
BACKGROUND: Childhood disruptive behavior problems are linked to aberrant integrity within large-scale cognitive control networks. However, it is unclear whether transitory or dynamic variation in the functional brain architecture is a marker of disruptive behavior problems. In this study, we tested whether functional connectivity across dynamic networks is distinctly associated with the transdiagnostic symptom domain of disruptive behavior problems in children. METHODS: Participants were 9 to 10-year-olds from the Adolescent Brain Cognitive Development Study who completed resting-state functional magnetic resonance imaging (fMRI) (N = 877). We used a dynamic connectivity approach leveraging a hidden semi-Markov model to identify transient properties of brain networks and states. Models estimated the time spent in each state (occupancy time) and the number of consecutive time points in a state (dwell time) for each participant. Linear regression models were utilized to identify distinct associations between dynamic properties (occupancy and sojourn times) and severity of disruptive behavior problems, while accounting for other commonly co-occurring symptoms. RESULTS: Dynamic network markers of disruptive behavior problems included increased time in network states characterized by globally aberrant connectivity patterns in circuitry involved in cognitive control including frontoparietal and dorsal attention networks. Reliability of findings was found in a held-out sample of resting-state fMRI runs in which greater severity of disruptive behavior problems was uniquely linked to greater occupancy time in similarly characterized brain states. CONCLUSIONS: Transdiagnostic, dynamic resting-state markers of disruptive behavior problems in youth may assist in the development of brain-based biomarkers for monitoring treatment outcomes, assessing circuit target engagement, and informing clinical decisions.