Literature DB >> 27875902

Nuisance Regression of High-Frequency Functional Magnetic Resonance Imaging Data: Denoising Can Be Noisy.

Jingyuan E Chen1,2, Hesamoddin Jahanian1, Gary H Glover1.   

Abstract

Recently, emerging studies have demonstrated the existence of brain resting-state spontaneous activity at frequencies higher than the conventional 0.1 Hz. A few groups utilizing accelerated acquisitions have reported persisting signals beyond 1 Hz, which seems too high to be accommodated by the sluggish hemodynamic process underpinning blood oxygen level-dependent contrasts (the upper limit of the canonical model is ∼0.3 Hz). It is thus questionable whether the observed high-frequency (HF) functional connectivity originates from alternative mechanisms (e.g., inflow effects, proton density changes in or near activated neural tissue) or rather is artificially introduced by improper preprocessing operations. In this study, we examined the influence of a common preprocessing step-whole-band linear nuisance regression (WB-LNR)-on resting-state functional connectivity (RSFC) and demonstrated through both simulation and analysis of real dataset that WB-LNR can introduce spurious network structures into the HF bands of functional magnetic resonance imaging (fMRI) signals. Findings of present study call into question whether published observations on HF-RSFC are partly attributable to improper data preprocessing instead of actual neural activities.

Entities:  

Keywords:  fast acquisition; high frequency; linear nuisance regression; resting state functional connectivity; spurious network structures

Mesh:

Substances:

Year:  2017        PMID: 27875902      PMCID: PMC5312601          DOI: 10.1089/brain.2016.0441

Source DB:  PubMed          Journal:  Brain Connect        ISSN: 2158-0014


  36 in total

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2.  Erroneous Resting-State fMRI Connectivity Maps Due to Prolonged Arterial Arrival Time and How to Fix Them.

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Review 6.  Incorporating structured assumptions with probabilistic graphical models in fMRI data analysis.

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7.  Resting-state "physiological networks".

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8.  A window-less approach for capturing time-varying connectivity in fMRI data reveals the presence of states with variable rates of change.

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9.  On the detection of high frequency correlations in resting state fMRI.

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10.  Energy-Period Profiles of Brain Networks in Group fMRI Resting-State Data: A Comparison of Empirical Mode Decomposition With the Short-Time Fourier Transform and the Discrete Wavelet Transform.

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