Litcius/Paper detail

A Critical, Event-Related Appraisal of Denoising in Resting-State fMRI Studies

Jonathan D. Power, Charles J. Lynch, Babatunde Adeyemo, Steven E. Petersen

2020Cerebral Cortex47 citationsDOI

Abstract

This article advances two parallel lines of argument about resting-state functional magnetic resonance imaging (fMRI) signals, one empirical and one conceptual. The empirical line creates a four-part organization of the text: (1) head motion and respiration commonly cause distinct, major, unwanted influences (artifacts) in fMRI signals; (2) head motion and respiratory changes are, confoundingly, both related to psychological and clinical and biological variables of interest; (3) many fMRI denoising strategies fail to identify and remove one or the other kind of artifact; and (4) unremoved artifact, due to correlations of artifacts with variables of interest, renders studies susceptible to identifying variance of noninterest as variance of interest. Arising from these empirical observations is a conceptual argument: that an event-related approach to task-free scans, targeting common behaviors during scanning, enables fundamental distinctions among the kinds of signals present in the data, information which is vital to understanding the effects of denoising procedures. This event-related perspective permits statements like "Event X is associated with signals A, B, and C, each with particular spatial, temporal, and signal decay properties". Denoising approaches can then be tailored, via performance in known events, to permit or suppress certain kinds of signals based on their desirability.

Topics & Concepts

Functional magnetic resonance imagingArtifact (error)Event (particle physics)Computer scienceNoise reductionResting state fMRIPerspective (graphical)Argument (complex analysis)Artificial intelligenceVariance (accounting)Communication noiseSIGNAL (programming language)Cognitive psychologyPsychologyPattern recognition (psychology)NeuroscienceBiochemistryPhysicsChemistryQuantum mechanicsProgramming languagePhilosophyAccountingLinguisticsBusinessFunctional Brain Connectivity StudiesNeural dynamics and brain functionEEG and Brain-Computer Interfaces