Litcius/Paper detail

Enhancing task fMRI preprocessing via individualized model‐based filtering of intrinsic activity dynamics

Matthew F. Singh, Anxu Wang, Michael W. Cole, ShiNung Ching, Todd S. Braver

2021NeuroImage17 citationsDOIOpen Access PDF

Abstract

Brain responses recorded during fMRI are thought to reflect both rapid, stimulus-evoked activity and the propagation of spontaneous activity through brain networks. In the current work, we describe a method to improve the estimation of task-evoked brain activity by first "filtering-out the intrinsic propagation of pre-event activity from the BOLD signal. We do so using Mesoscale Individualized NeuroDynamic (MINDy; Singh et al. 2020b) models built from individualized resting-state data to subtract the propagation of spontaneous activity from the task-fMRI signal (MINDy-based Filtering). After filtering, time-series are analyzed using conventional techniques. Results demonstrate that this simple operation significantly improves the statistical power and temporal precision of estimated group-level effects. Moreover, use of MINDy-based filtering increased the similarity of neural activation profiles and prediction accuracy of individual differences in behavior across tasks measuring the same construct (cognitive control). Thus, by subtracting the propagation of previous activity, we obtain better estimates of task-related neural effects.

Topics & Concepts

Brain activity and meditationPreprocessorComputer scienceArtificial intelligenceNeural activityTask (project management)Functional magnetic resonance imagingPattern recognition (psychology)Similarity (geometry)Resting state fMRIArtificial neural networkPsychologyNeuroscienceElectroencephalographyManagementImage (mathematics)EconomicsFunctional Brain Connectivity StudiesNeural dynamics and brain functionEEG and Brain-Computer Interfaces
Enhancing task fMRI preprocessing via individualized model‐based filtering of intrinsic activity dynamics | Litcius