2.1.

Subject Population

In this study, a total of 22 subjects (15 males, 7 females; age range 21 to 45 years; all right handed) were recruited for functional imaging studies. All subjects provided written informed consent prior to study procedures. This study was approved by the University of Pittsburgh Institutional Review Board.

The study consisted of two separate scanning sessions for the MEG-fNIRS and MRI-fNIRS. The MEG-fNIRS scan was done first in all cases due to the potential loss of subjects whose head size or body dimensions precluded them from MEG scanning. A total of four subjects was excluded prior to scanning because their head would not fit inside the MEG scanner while wearing the fNIRS sensors. A further two subjects failed to yield adequate fNIRS signals after initial setup and were excluded. The remaining 16 subjects were scanned with concurrent fNIRS-MEG. Of the 16 remaining subjects, 11 were additionally scanned inside the MRI with concurrent fNIRS. Five subjects were lost to follow-up or withdrew from the study after the first visit. Of the 11 subjects that completed both the MEG and fMRI sessions, a further 4 were rejected due to excessive eye-blink or head motion artifacts in the MEG analysis. Thus, a final total of 7 subjects (4 males, 3 females) were used in the final analysis of the study having completed all aspects of the protocol.

2.2.

Experimental Protocol

Unilateral median nerve stimulation was conducted using a computer controlled GRASS S88X stimulator (Natus Neurology Inc., Warwick, Rhode Island). A stimulating bar electrode was positioned on the right median nerve and the voltages were adjusted to match the motor threshold as judged by twitching of the thumb on the stimulated hand. The stimulating voltage was then set at the determined motor-threshold for the study. The median nerve stimulation had duration of $20\mu \mathrm{s}$ with a monophasic pulse. Two experimental tasks were performed. First, a functional localizer task consisting of repeated 10-s blocks of stimulation at 4 Hz with a 10-s interblock rest period (5 min total time; 15 blocks) was administered. The purpose of this task was to provide spatial localization information to define regions-of-interest to the pulsed-pair stimulation task. Second, several 5-min scans of event-related pulsed-pair stimulation were then given. The pulsed-pair condition consisted of a pair of two median nerve pulses separated by an interstimulus interval of 50, 100, 150, 200, 300, 400, or 500 ms. The stimulus conditions were presented in randomized order with a minimum spacing of 8-s between events to avoid potential nonlinearity in the hemodynamic response based on the work by Cannestra et al.,¹⁶ which suggested a minimum of 4-s interval was required. A total of 32 pairs of stimulus events was delivered in each 5-min scan. This scan was repeated 4 to 6 times per subject depending on subject tolerance and time constraints. The experimental procedure for both the MEG-NIRS and MRI-NIRS portions of the study were identical. An MEG-compatible bar electrode obtained from Elekta Neuromag (Helsinki, Finland) was used in this study. An identical duplicate electrode was used for the MRI portion of the study, which was verified to have negligible RF-heating and no ferromagnetic characteristics.

In order to control the stimulus timing, a custom dynamically linked library (DLL) was written to digitally interface to the GRASS stimulator via a universal serial bus cable. This allowed digital control of the frequency and duration of the stimulation with microsecond precision. An experimental paradigm was written in Eprime-2 (Psychology Software Tools; Pittsburgh, Pennsylvania) to control the GRASS device via the custom DLL program to prime the stimulator with the correct pulse interval several seconds prior to stimulation. The start of each stimulus event was triggered by Eprime and the GRASS device then controlled the timing of the second pulse. In this way, the pulsed-pair stimulus was delivered with better than millisecond precision as measured by the MEG auxiliary channel. The stimulus output from the GRASS device was sent to both the fNIRS and MEG systems for recording. A current isolation device was used to limit stimulation of the subject.

2.3.

Analysis Methods

A schematic overview of our complete multimodal analysis pipeline is shown in Fig. 1. A key feature of this pipeline is the use of the subject anatomy and cortical surface model generated by the FreeSurfer tools available from the Massachusetts General Hospital.¹⁷ The extracted cortical surfaces, which are registered among subjects to allow group analysis, are used in all three functional imaging modalities, which allows direct comparisons of each modality. The individual components of this pipeline are described as follows.

Fig. 1

A schematic overview of the fNIRS/MEG/fMRI analysis pipeline (described in text). Analysis of all three modalities is performed in the space of the segmented and inflated cortical surface obtained from the FreeSurfer tools.

2.4.

MEG Acquisition and Analysis

MEG data were collected using a whole-head 306-channel Elekta Neuromag^® Vectorview system (Elekta Neuromag Oy, Helsinki, Finland). Concurrent electrooculogram (EOG) was also acquired. This system is composed of 102 triple-sensors consisting of a magnetometer, longitudinal gradiometer, and a latitudinal gradiometer and is contained inside a magnetically shielded room (MSR). During the acquisition, subjects were inside the MSR ($\sim 4.6\mathrm{m}\times 3.6\mathrm{m}\times 3\mathrm{m}$ in dimension) sitting comfortably with their head positioned in a helmet containing the sensors (Fig. 2). MEG scans were sampled at 1000 Hz and subsequently down-sampled offline to 250 Hz. The MEG channels were manually inspected and obviously bad channels were removed from further analysis. The MEG signals were then bandpass filtered using cutoffs of 1 and 50 Hz to remove the 60 Hz line noise and slow drifts. Temporal spatial signal separation (tSSS) was employed to remove external magnetic field contributions in the signal recordings, which can lead to spurious signals that appear to have originated from physiological changes but are in fact artifacts external to the MEG sensors.¹⁸ Data were then averaged into trials and trials with excess eye blinks or eye movements, as assessed by the maximal difference in the EOG over the trial, were rejected. Data from each condition were subsequently averaged offline.

Fig. 2

Simultaneous fNIRS with fMRI (left) and fNIRS with MEG (right) were recorded in two separate sessions. The center panels show the localization of the fiducial markers used to register the fNIRS probe in the MRI (top) and MEG (bottom) images.

For source localization, the cortically constrained minimum norm estimate (MNE) inverse solution was employed using the MNE^™ software suite v2.7.¹⁹ Briefly, a linear inverse operator $W$ is applied to the measured signal to calculate the MNE

For group-level maps, the data from each participant was morphed onto a common brain. Statistical values were assessed using a paired $t$-statistic across the seven participants for the MEG response to the median nerve stimulation versus prestimulation baseline. The peak time was chosen individually for each subject based on the time that showed the greatest change relative to baseline averaged across all MEG sensors ($\text{mean}=74.4\mathrm{ms}$; $\mathrm{std}=15.5\mathrm{ms}$). For the ROI analysis, ROIs were drawn at the individual subject level. The ROI corresponding to primary somatosensory cortex was determined from the response in the functional localizer scan relative to prestimulus time and applied to the pulsed-pair condition.

2.5.

MRI Acquisition and Analysis

Structural and functional MRI was performed using a 3T Siemens TIM TRIO scanner using a 12-channel head coil. A structural T1-weighted image was acquired (Siemens’ MPRAGE; $176\times 256\times 192$ 1 mm isotropic; $\mathrm{TE}=3.52\mathrm{ms}$; $\mathrm{TR}=2300\mathrm{ms}$). A total of 4 to 6 5 min BOLD EPI scans were performed ($64\times 64\times 31$ 3.5 mm isotropic; $\mathrm{TR}=2000\mathrm{ms}$; $\mathrm{TE}=30\mathrm{ms}$; $\mathrm{FA}=90\mathrm{deg}$). Functional MRI analysis was performed using the AFNI and SUMA toolset from the NIH.^24,25 In brief, functional EPI data were coregistered to the structural volume and motion corrected to the third TR. The slices were temporally aligned and volumes were blurred using the default 4-mm FWHM kernel. General linear model analysis based on the timing of the seven pulsed-pair and localizer-conditions was performed using the default gamma-variant canonical basis function (GAM)¹ with additional motion regressor terms. Group level ANOVA was performed within AFNI.

The structural T1-weighted anatomical MRI image for each subject was processed using the FreeSurfer pipeline in order to generate the segmented anatomical models and registered cortical surface models used for fNIRS, MEG, and fMRI analysis procedures. Following registration and brain segmentation using Freesurfer, the MNE toolkit²² was used to additionally create boundary element models for the skin and outer/inner skull, which allowed construction of a 5-layered head model (skin, skull, CSF, gray matter, and white matter) for each subject which was used to generate the fNIRS forward model using the optical properties described in Fang and Boas²⁶ for the 690- and 830-nm wavelengths. The Monte Carlo program tMCimg²⁷ was used to simulate the optical forward model. The same boundary element and brain surface models were used to generate the MEG forward model as part of the MNE MEG analysis pipeline developed by Hamalainen et al. at the Massachusetts General Hospital.²² The extracted white matter and pial brain surfaces from FreeSurfer were used in the inverse models for both fNIRS and MEG and for the SUMA-AFNI^24,25 surface analysis of the fMRI data. In this way, the estimates of brain activation from all three modalities were derived in the same cortical surface space for direct comparisons of the results.

2.6.

fNIRS Acquisition

For both MRI and MEG portions of the study, fNIRS signals were recorded using a commercial TechEn CW6 (Milford, Massachusetts) continuous-wave fNIRS system. This system contains up to 16 laser diodes each at 690 and 830 nm (12 and 8 mW, respectively), which are coupled through fiber optic cables mounted onto a head cap. The head cap was constructed of Velcro and plastic materials and was custom built for this study. Due to the limitations of head-clearance inside the MEG scanner, the fNIRS cap had to be restricted to eight detectors and four source positions containing both wavelengths on only one hemisphere of the head. The same design was used for both parts of the study although dedicated identical sets of fiber optics and head caps were used to avoid magnetic contamination of the MEG. The probe extended from left frontal cortex (near 10 to 20 coordinate “F3”) to posterior partial (near 10 to 20 coordinate “P3”) with a source–detector spacing of 3.2 cm as shown in Fig. 2.

2.7.

MEG-fNIRS Setup

The fNIRS cap used in this study had a profile height of 11 mm, which reduced the spacing between the MEG SQUID detectors and the subject’s head. Four head position indicator (HPI) coils were glued to the subject’s scalp using collodion gel. These were used to coregister the fNIRS and MEG sensor positions after positioning the fNIRS cap on the subject’s head. Two electrodes were positioned above and below the left eye and above the corner of the left eye and below the corner of the right eye to monitor eye blinks and saccades. Cardiac activity was recorded on an ECG channel using two electrodes that were attached just below the collarbone of the subjects. Prior to MEG scanning, a Polhemus Isotrack (Polhemus, Inc., Colchester, Vermont) positioning system (integrated with the MEG acquisition software) was used to register the HPI coils and to landmark fiducial points (nasion and preauricular points) on the subject’s head. These were then used to register both the fNIRS and MEG sensor locations to the subject’s anatomical MRI data. Based on previous work, we expect the localization error of this method to be around 3 to 5 mm.²⁸ Additional points (up to 100) were digitized on the subject’s head and face to help facilitate coregistration of MEG data with the structural MRI’s. Immediately prior to MEG acquisitions, the HPI coils were energized and their positions localized through the MEG acquisition interface. This registration information was then extracted from the MEG data files and combined with the location of the fNIRS sensors from the isotrack data using a rigid-body transform to localize the fNIRS sensors on the registered MRI volumes from the second session.

For fNIRS recordings, an MEG-dedicated set of fiber optics (10-m long) was passed through the access port (wave-guide) in the side of the MSR. The fNIRS instrument was located next to the MEG acquisition computers. The stimulus timing from the median nerve device was sent to both the MEG and fNIRS instruments through auxiliary recording channels built into both systems. Because the fNIRS instrument was sampled at a lower rate, a 555-timer pulse-elongating circuit had to be constructed to elongate the $20\text{-}\mu \mathrm{s}$ stimulating pulse to 500 ms for recording by the fNIRS system.

2.8.

MRI-fNIRS Setup

Functional NIRS collection during the MRI portion of the study was similar to the MEG collection with the exception that a MRI-dedicated set of 10-m fiber optics and head cap was used to avoid magnetic contamination to the MEG system. The CW6 instrument was positioned in the control room for the MRI scanner and the fiber optics were run through the MR waveguide into the scanner room. The fNIRS head cap used in the MRI portion of study was identical to the one used in the MEG portion of the study. The head cap contained vitamin E capsules in place of the four MEG HPI coil positions, which were used for registration of the cap from the T1-weighted MRI image for each subject. In previous work, we have estimated the registration error of this approach to be about 5 mm.¹⁴ The timing of the stimulus paradigm was triggered from the MRI scanner.

2.9.

fNIRS Analysis

Analysis of fNIRS results was performed using custom MATLAB scripts. Raw 20-Hz fNIRS data were converted to optical density (absorption) at both 690 and 830 nm for all measurement pairs. The unfiltered optical density data for all measurement pairs were then analyzed using a statistical general linear model as described in Barker et al.¹¹ This model uses an iterative estimation of an autoregressive (AR) whitening filter and weighted-least-squares regression to reduce the effects of serially correlated noise and motion artifacts in the fNIRS data. In brief, a regression model (design matrix; $\mathbf{X}$) was constructed from convolution of a canonical hemodynamic response function (default AFNI GAM¹ function;²⁴) with the stimulus onsets and durations of the median nerve stimulation events. Thus, a linear regression model is constructed of the form $Y=\mathbf{X}·\beta$, where $Y$ is the vector of time-points for each optical measurement pair (optical density) and $\beta$ is the estimated weights of the regressors. The values of $\beta$ are first estimated from a weighted least-squares procedure, which reduces the influence of noise outliers (robustfit function in MATLAB²⁹). A $p$th-order AR model is then fit to the residual error of the regression fit where $p$ is estimated by an AIC criteria search. The AR coefficients are used to construct a whitening filter (${\mathbf{S}}^{-1}$), which is applied to both the left and right hand sides of the regression model (e.g., ${\mathbf{S}}^{-1}·Y={\mathbf{S}}^{-1}·\mathbf{X}·\beta$). The regression model is again solved using robust regression methods and the procedure is iterated until convergence (usually within 2 to 3 iterations). This is repeated for each optical measurement channel and wavelength. Our previous work in developing this model, described in Barker et al.,¹¹ had shown that this model was robust to both spike and shift types of motion artifacts in the fNIRS data. In particular, the presence of infrequent, large amplitude motion artifacts in the fNIRS data results in a heavy-tailed statistical distribution of noise, which can be addressed with robust regression methods to treat these outliers. In addition, we had shown that correction for serially correlated errors due to systemic physiology and drifts produced much more accurate estimates of model errors and type-I error rates compared to least squares estimation. Thus, this model is fairly robust to false-discoveries due to superficial physiological contamination.¹¹ This model performs best when raw (unfiltered) data are used since removing portions of the frequency spectrum can make the prewhitening procedure ill-posed and the algorithm numerically unstable.

The outputs of the regression models (e.g., estimates of $\beta$ and the estimate of the covariance errors in $\beta$ associated with the optical density changes for each fNIRS measurement channel) were then reconstructed into estimates of brain activity. For image reconstruction, we used a random-effects cortical surface topography model, which had been previously described in Abdelnour et al.¹³ In this model, this fNIRS forward model (sensitivity model) is computed on the cortical surface of the brain using the extracted surfaces from the Freesurfer model described in the previous section. Of note, this same cortical surface is also used in the MEG and fMRI models via AFNI-SUMA. The registered “spherical” inflated surface for each hemisphere from the Freesurfer model is reparameterized using spherical wavelet basis set described in Abdelnour et al.¹⁴ Spherical wavelets are used to describe the image (e.g., brain activity map) on the surface of the cortex at different spatial resolutions similar to more conventional wavelet representations with the distinction that these spherical wavelets are specifically designed to model a two-dimensional topography on a closed three-dimensional surface. The spherical wavelets are derived from a recursive subdivision of an icosahedral mesh, which can easily be extracted from the existing Freesurfer cortical surfaces from the icosahedral levels 1 to 4 (2562 nodes per hemisphere with about 6.2-mm vertex spacing and $39\text{-}{\mathrm{mm}}^2$ face areas). Since the registered “spherical” surfaces are used in the FreeSurfer model for each subject, the spherical wavelets map on to approximately the same anatomical regions across subjects. For example, the $n$th parameter in the model represents brain activation at the same cortical gyrus for all subjects even though that gyrus may be in a slightly different Cartesian location in the space of the pial brain surface. Of further note, this surface mapping feature of the Freesurfer models allows activations to be transferred and averaged among subjects and is used in both the AFNI-SUMA and MEG-MNE pipelines for group level models. We note that this is the same convention and mesh used in the MEG MNE reconstruction through the Freesurfer pipeline.

Because the spherical wavelet model parameterizes each individual subject’s fNIRS forward model into the same registered brain space, the models for all subjects can be concatenated into a single large random-effects inverse model and solved simultaneously for all subjects. Our random-effects group level fNIRS model was previously described in Abdelnour et al.¹³ In brief, this group level analysis model is similar to the group-level image reconstruction of MEG data described in Mattout el al.³⁰ The fNIRS forward model for all individual subjects ($L_i$) can be concatenated into a single-inverse operator such that

In this random-effects model, each individual subject’s image is modeled as a perturbation on the group average (e.g., ${\beta }_1={\beta }_{\text{Group}}+\mathrm{\Delta }{\beta }_1$). Because the fNIRS inverse model is ill-posed (meaning that there are a large number of equally plausible solutions that model the data), this random-effects approach attempts to find an estimate of the group average that is self-consistent with all the individual subjects. Our previous work¹³ had shown that this approach resulted in a much smaller point-spread function and higher effect sizes in group-level analysis compared to a more conventional two-step approach of reconstructing each individual subject and then averaging the results. While this approach has also been shown to be effective in MEG analysis,³⁰ this is not yet implemented in the MEG pipeline used by MNE and thus, it is important to point out that our MEG processing still used this two-step approach.

The fNIRS random-effects inverse model was solved using a hierarchical Bayesian model as described by Abdelnour et al.¹³ Restricted maximum likelihood and expectation–maximization recursion was used to estimate the noise hyper-parameters of the model. The covariance of the regression coefficients from the general linear model ($\beta$) was used to construct the covariance prior on the measurement noise, whereas a scalar identity operator was used to model oxy- and deoxy-hemoglobin priors. Thus, a total of three hyper-parameters ($\lambda$) are estimated in this model. A description of the algorithm is found in Abdelnour et al.¹³ and follows the description of the hierarchal inverse model used in the MEG and EEG image analysis in SPM.^30,31

3.1.

Pulsed Pair Results

In the second half of the study, we performed an event-related pulsed-pair median nerve study. The pulsed-pair task uses two stimuli placed 50 to 500 ms apart. A slow event-related design with a minimum 8-s ISI was used to avoid additional nonlinearity in the hemodynamic response unrelated to the neural-refractory effect.¹⁶ As shown in Fig. 6, when the second pulse was $<200\mathrm{ms}$ after the first, the MEG ERP response was significantly diminished by the neural refractory period. At 300 ms and later, the second ERP response was again visible. A similar task had previously been used by Ogawa et al.³³ showing a similar effect in rodent forepaw stimulation and was more recently examined for multimodal fMRI-MEG by Stevenson et al.³⁴ Using the region-of-interest defined as the union of activations from all of the modalities observed in the localizer task the magnitude of brain activity for all seven interpair intervals was calculated from each modality.

Fig. 6

MEG ERP responses. The estimated MEG evoked responses for the seven pulsed-pair conditions are shown. For short inter-pulse intervals ($<300\mathrm{ms}$), the second pulse falls in the neural-refractory period and does not provide a strong ERP response. After 400 ms, the second ERP response is visible in the MEG data. The plots show the grand average across all subjects.

In Fig. 7, grand average of the normalized magnitude of the MEG [area-under-curve $(\mathrm{AUC})={\sum }_{t=0}^{600\mathrm{ms}}|\mathrm{ERP}(t)|$], fMRI, and fNIRS signals for the pulsed-pair conditions is presented. The signals are shown normalized to the mean of the seven conditions. We found significant correlations of $R=0.80$, 0.52, and $-0.70$ between the magnitude of the fMRI and fNIRS [oxy-/deoxy-hemoglobin] responses compared with the AUC of the MEG response using colocalized regions-of-interest. The BOLD and fNIRS magnitudes were also significantly correlated for oxy- and deoxy-hemoglobin responses ($R=0.27$ and $-0.89$, respectively).

Fig. 7

Pulsed pair responses. The magnitude of the evoked response to the pulsed-pair stimulation conditions was estimated from a region-of-interest defined as the intersection of the MEG, fNIRS, and fMRI responses. The mean normalized MEG area-under-the-curve and estimated hemodynamic responses are shown for the seven interpulse intervals. The plots show the grand average across all subjects.

In addition, the amplitude of the evoked pulsed-pair response was also estimated using modality-specific regions-of-interest. For the fNIRS data, the region-of-interest was defined in fNIRS channel (source–detector) space as the average value over all statistically significant channels ($p<0.05$) on the probe. Using the modality-specific regions-of-interest, we still found statistically significant ($p<0.05$) correlations between the MEG signal (AUC) and the fNIRS channel oxy- and deoxy-hemoglobin data from the MEG-fNIRS session ($R=0.75$ and $-0.69$, respectively). The fNIRS channel-based correlations to the MRI-BOLD signal went for down to $R=0.26$ and $-0.46$ for oxy- and deoxy-hemoglobin. These lower correlations observed in fNIRS channel space compared to the reconstructed images may be due to errors introduced from intersubject registration and anatomy, which are accounted for in the image reconstruction process but not in the raw channel space data.