Introduction
Studies integrating functional near-infrared spectroscopy (fNIRS) with functional MRI (fMRI) employ heterogeneous methods in defining common regions of interest in which similarities are assessed. Therefore, spatial agreement and temporal correlation may not be reproducible across studies. In the present work, we address this issue by proposing a novel method for integration and analysis of fNIRS and fMRI over the cortical surface.
Materials and methods
Eighteen healthy volunteers (age mean±SD 30.55 ± 4.7, 7 males) performed a motor task during non-simultaneous fMRI and fNIRS acquisitions. First, fNIRS and fMRI data were integrated by projecting subject- and group-level source maps over the cortical surface mesh to define anatomically constrained functional ROIs (acfROI). Next, spatial agreement and temporal correlation were quantified as Dice Coefficient (DC) and Pearson’s correlation coefficient between fNIRS-fMRI in the acfROIs.
Results
Subject-level results revealed moderate to substantial spatial agreement (DC range 0.43 – 0.64), confirmed at the group-level only for blood oxygenation level-dependent (BOLD) signal vs. (0.44 – 0.69), while lack of agreement was found for BOLD vs. in some instances (0.05 – 0.49). Subject-level temporal correlation was moderate to strong (0.79 – 0.85 for BOLD vs. and −0.62 to −0.72 for BOLD vs.), while an overall strong correlation was found for group-level results (0.95 – 0.98 for BOLD vs. and −0.91 to −0.94 for BOLD vs.).
Conclusion
The proposed method directly compares fNIRS and fMRI by projecting individual source maps to the cortical surface. Our results indicate spatial and temporal correspondence between fNIRS and fMRI, and promotes the use of fNIRS when more ecological acquision settings are required, such as longitudinal monitoring of brain activity before and after rehabilitation.
