NeuroImage (Apr 2024)

Spatial correspondence of cortical activity measured with whole head fNIRS and fMRI: Toward clinical use within subject

  • Anthony Zinos,
  • Julie C. Wagner,
  • Scott A. Beardsley,
  • Wei-Liang Chen,
  • Lisa Conant,
  • Marsha Malloy,
  • Joseph Heffernan,
  • Brendan Quirk,
  • Robert Prost,
  • Mohit Maheshwari,
  • Jeffrey Sugar,
  • Harry T. Whelan

Journal volume & issue
Vol. 290
p. 120569

Abstract

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Functional near infrared spectroscopy (fNIRS) and functional magnetic resonance imaging (fMRI) both measure the hemodynamic response, and so both imaging modalities are expected to have a strong correspondence in regions of cortex adjacent to the scalp. To assess whether fNIRS can be used clinically in a manner similar to fMRI, 22 healthy adult participants underwent same-day fMRI and whole-head fNIRS testing while they performed separate motor (finger tapping) and visual (flashing checkerboard) tasks. Analyses were conducted within and across subjects for each imaging approach, and regions of significant task-related activity were compared on the cortical surface. The spatial correspondence between fNIRS and fMRI detection of task-related activity was good in terms of true positive rate, with fNIRS overlap of up to 68 % of the fMRI for analyses across subjects (group analysis) and an average overlap of up to 47.25 % for individual analyses within subject. At the group level, the positive predictive value of fNIRS was 51 % relative to fMRI. The positive predictive value for within subject analyses was lower (41.5 %), reflecting the presence of significant fNIRS activity in regions without significant fMRI activity. This could reflect task-correlated sources of physiologic noise and/or differences in the sensitivity of fNIRS and fMRI measures to changes in separate (vs. combined) measures of oxy and de-oxyhemoglobin. The results suggest whole-head fNIRS as a noninvasive imaging modality with promising clinical utility for the functional assessment of brain activity in superficial regions of cortex physically adjacent to the skull.

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