Sensorimotor functional connectivity: A neurophysiological factor related to BCI performance [original]

ORIGINAL RESEARCH
published: 18 December 2020
doi: 10.3389/fnins.2020.575081
Frontiers in Neur oscience | www .fr ontiersin.org 1 December 2020 | V olume 14 | Article 575081
Edited by:
Paul Watters,
Independent Researcher , Melbourne,
Australia
Reviewed by:
Soha Saleh,
Kessler Foundation, United States
José Ramón Villar ,
University of Oviedo, Spain
*Correspondence:
Carmen Vidaurre
[email protected]
Klaus-Robert Müller
[email protected]
V adim V . Nikulin
[email protected]
Specialty section:
This article was submitted to
Brain Imaging Methods,
a section of the journal
Frontiers in Neuroscience
Received: 22 June 2020
Accepted: 16 November 2020
Published: 18 December 2020
Citation:
Vidaurre C, Haufe S, Jorajuría T ,
Müller K-R and Nikulin VV (2020)
Sensorimotor Functional Connectivity:
A Neurophysiological Factor Related
to BCI Performance.
Front. Neurosci. 14:575081.
doi: 10.3389/fnins.2020.575081
Sensorimotor Functional
Connectivity: A Neur ophys iological
Factor Related to BCI Performance
Carmen Vidaurre 1 * , Stefan Haufe 2, 3 , T ania Jorajuría 1 , Klaus-Robert Müller 4, 5, 6, 7 * and
V adim V . Nikulin 8, 9 *
1 Department of Statistics, Computer Science and Mathematics, Public University of Navarre, Pamplona, Spain, 2 Berlin
Center for Advanced Neuroimaging, Charité – Universitätsmedizin Berlin, Berlin, Germany , 3 Bernstein Center for
Computational Neuroscience Berlin, Berlin, Germany , 4 Department of Machine Learning, Berlin University of T echnology ,
Berlin, Germany , 5 Department of Artificial Intelligence, Korea University , Seoul, South Korea, 6 Max Planck Institute for
Informatics, Saarbrücken, Germany , 7 Google Research, Brain T eam, Berlin, Germany , 8 Department of Neurology , Max
Planck Institute for Human Cognitive and Brain Sciences, Leipzig, Germany , 9 Center for Cognition and Decision Making,
Institute for Cognitive Neuroscience, National Research University Higher School of Economics, Moscow , Russia
Brain-Computer Interfaces (BCIs) are systems that allow users to control devices using
brain activity alone. However , the ability of participants to command BCIs varies from
subject to subject. About 20% of potential users of sensorimotor BCIs do not gain
r eliable control of the system. The inef ficiency to decode user’ s intentions r equires
the identification of neurophysiological factors determining “good” and “poor” BCI
performers. One of the important neurophysiological aspects in BCI r esearch is that
the neuro nal oscillations, used to control these systems, show a rich repertoir e of
spatial sensorimotor interactions. Considering this, we hypothesized that neuronal
connectivity in sensorimotor areas would define BCI performance. Analyses for this
study were performed on a large dataset of 80 inexperienced participants. They took
part in a calibration and an online feedback session r ecorded on the same day .
Undir ected functional connectivity was computed over sensorimotor areas by means of
the imaginary part of coherency . The r esults show that post- as well as pre-stimulus
connectivity in the calibration recor ding is significantly correlated to online feedback
performance in µ and feedback frequency bands. Importantly , the significance of the
corr elation between connectivity and BCI feedbac k accuracy was not due to the
signal-to-noise ratio of the oscillations in the corresponding post and pr e-stimulus
intervals. Thus, this study demonstrates that BCI performance is not only dependent
on the amplitude of sensorimotor oscillations as shown previously , but that it also
r elates to sensorimotor connectivity measured during the preceding training session.
The presence of such connectivity between motor and somatosensory systems is likely
to facilitate motor imagery , which in tur n is associated with the generation of a more
pr onounced modulation of sensorimotor oscillations (manifested in ERD/ERS) r equired
for the adequate BCI performance. W e also discuss strategies for the up-regulation of
such connectivity in order to enhance BCI performance.
Keywords: connectivity , sensorimotor signals, BCI performance, µ -band, BCI efficiency , pre-stimulus

Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
1. INTRODUCTION
Brain Computer Interfaces (B CIs) were developed with th e
aim to offer patients suffering from loss of voluntary motor
abilities devices to increase their capacity to control and
communicate with their environment. B CIs b ased on the
modulation of Sensorimotor R hythms (SMR) use brain signals
recorded during the performance of movement imagination or
movement attempt to extract features that allow the classification
of different motor imagery (MI) tasks ( Neuper and Pfurtscheller,
2001; Wolpaw et al., 2002; Dornhege et al., 2007; Blankertz et al.,
2008; Lemm et al., 2011; Müller -Putz et al., 2015; Sannelli et al.,
2019 ). SMR are oscillatory signals generated in the sensorimotor
areas of the cortex. In general, os cillatory signals are divided
within frequency ranges. µ (9–14 Hz) and β (15–25 Hz) bands
are particularly important for MI feature extraction ( Neuper and
Pfurtscheller, 2001; Wolpaw, 2007; Millán et al., 2010; Blankertz
et al., 2011; V idaurre et al., 2013; Sannelli et al., 2019 ).
A modulation of brain activity in µ and β bands has
been obser ved in relation to motor execution ( Salmelin and
H ari, 1994; Pfurtscheller et al., 1997; Klopp et al., 2001 ),
motor preparation ( Pfurtscheller and Neuper, 1997; Pineda,
2005 ), somatosensory processing ( Nikulin et al., 2007 ), and
motor imagery ( Neuper et al., 2005; Pfurtscheller et al., 2006;
Bauer et al., 2015 ). Due to its malle ability induced by diver se
aspects of sensorimotor processing, µ rhythm ser ves as the
main neuronal signal for sensorimotor B CI based on MI
( Leuthardt et al., 2004; Buch et al., 2008; Waldert et al., 2008;
Nierhaus et al., 2019; Sannelli et al., 2019 ).
Furthermore, the power of sensorimotor oscillations in t he
µ -band during resting state, has been established as a predictor
of SMR -b ased BCI per formance in two different large scale
studies ( Blankertz et al., 2010; A cqualagna et al., 2016 ). In
addition, spatio-temporal features based on power values in
µ and β bands of resting state dat a ha ve also been used to
predict B CI performance ( Blankertz et al., 2010; Suk et al.,
2014 ). Considering the power in other frequency bands, Ah n
et al. (2013b) found that oscillatory activity at hig h θ and low
α frequency were present in users who could not attain B CI
control. Grosse-Wentrup et al. (2011) showed that γ activity
in the fronto-parietal network is related to subject-specific MI
performance variations. Also in Ahn et al. (2013a) , it was found
that pre-frontal γ band activity is positively correlated wit h
MI performance, concluding that concentration as mental state
could be used to predict MI performance. Finally, Robinson et al.
(2018) showed that the resting state activation patterns such
as γ power from pre-motor and posterior areas, and β power
from posterior areas can be used to estimate B CI performance.
In summary, power of brain oscillations at different frequency
bands has been successfully established as BCI per formance
predictor. Importantly, these measures t hat are directly based
on the power of oscillations, c an explain BCI per formance
variations that are due to signal-to-noise ratio (SNR) changes.
However , also ot her measures not directly defined by the
power of oscillations, should be utilized in order to shed light
into neurophysiological aspects of neuronal activity defining
B CI performance.
Regarding such neurophysiological predictors, Samek et al.
(2016) showed that long-range temporal correlations, estimated
with Hurst exponents in calibration recordings, could predict
the subsequent performance of feedback recordings. Also Zhang
et al. (2015) could find a significant correlation between B CI
performance and spectral entropy in the b and between 0.5 and 14
Hz. In addition H ammer et al. (2012) could establish correlates of
psychological variables and BCI performance.
From a structural perspective, H alder et al. (2011) showed that
the number of activated voxels in the supplementary motor area
of participants with good B CI performance was greater t han for
those demonstrating worse performance. Then, in H alder et al.
(2013) it was shown that the structural integrity and myelination
quality of deep white matter structures were significantly
correlated to B CI performance. The structural white matter
integrity as measured by fractional anisotropy (F A) has also
been significantly correlated to idle α peak ( V aldés-Hernánde z
et al., 2010 ), which occurs in the same frequency range as µ
rhythms. Finally, Zhang et al. (2016) showed that the fronto-
parietal attention network (measured by MRI) is correlate d to
B CI performance using structural (cortical thickness) as well
as functional connectivity features (eigenve ctor centrality and
degree of centrality).
Regarding connectivity of non-invasive time-resolved signals,
phase synchrony of magneto encephalographic (MEG) signals
in the µ -band has also been related to B CI performance in
Sugata et al. (2014) . There, the authors found a significant
correlation between the strength of the imaginary part of
coherency ( Nolte et al., 2004, 2008 ) and estimated (offline)
B CI performance in data of 10 participants. In that work,
imaginary coherency (iCOH) was estimated between M1 and
motor association areas in the post-stimulus inter val of t he trial.
Although this is a n interesting result, the study presented two
drawbacks: first, iCOH and B CI performance were estimated
in exactly the same trials and the s ame time inter val, and
second, B CI performance was estimated by cross-validation of
an off-line (without online feedback) session. Thus, the ability of
iCOH to predict future B CI accuracy has not been established
yet. Furthermore, those correlations were not tested against
the influence of the power (signal-to-noise-ratio, SNR) of the
signals, that as aforementioned has been s hown to significantly
correlate to B CI performance. Additionally, Bayraktaroglu et al.
(2013) showed that SNR might influence coherency values, with
large amplitudes of oscillatory signals (large power , large SNR)
producing larger iCOH values than lower ones. All this previous
evidence indicates the need to study the effect of SNR on
connectivity values. Finally, since the analysis was performed
only in the post-stimulus inter val, the question remains wheth er
the relation between connectivity and B CI performance could
also be extended to the pre-stimulus inter val, which in turn
would indicate that general trait-like connectivity patterns might
define B CI performance.
The study presented here is in relation to our previous work
published in V id aurre et al. (2019) . There, we obser ved in
calibration data of 20 subjects that iCOH of pre and post-central
gyri extracted during the post-stimulus inter val of MI concurrent
to submotor threshold neuromuscular electrical stimulation was
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
FIGURE 1 | Experimental design of the BCI session. (T op left) Calibration trial timing. (T op right) Details of the calibration recor ding (3 runs of 75 trials each and 25
trials per class, left hand, right hand, and feet motor imagery). (Bottom left) Feedback trial timing. (Bottom right) Details of the feedback session (3 runs of 100 trials
each and two subject-dependent classes).
significantly higher than t hat of MI. We also found that post-
stimulus functional connectivity estimated using parameters
extracted from MI data with simult aneous muscular stimulation
was significantly correlated to calibration performance on a
classifier trained with motor imagery and afferent signals. Here,
we rather concentrate on motor imagery alone in the typical
calibration vs. online recording paradigm. We aim to study
whether pre- and post-stimulus imaginary coherence of within
and/or across sensorimotor connectivity of calibration data c an
predict future feedback (online) performance in a group of 80
participants. Besides, and taking into account that t he dynamics
of the data are individual ( Ricci et al., 2019; T atti et al., 2019 ), we
systematically control for the influence t hat SNR of the oscillatory
signals might have on the extracted connectivity estimates.
2. MA TERIALS AND METHODS
2.1. Experimental Setup
Eighty healthy B CI-novices took part in t he study (41 female, age
29.9 ± 11.5 years; 4 left-handed). Calibration and feedback runs
were recorded in a single session.
The participants were sitting in a comfortable chair with
arms lying relaxed on armrests. Brain activity was re corded
using electroencephalographic (EEG) amplifiers (BrainAmp D C
by Brain Products, Munich, Germany). For this study we
selected 61 channels, referenced at nasion of an extended 10–
20 system. The recorded signals were down-sampled at 100 H z
after filtering the data between 0.5 and 45 Hz. Calibration runs
lasted approximately 15 min with three different visual cues, e ach
of them representing one motor imagery task (left hand, right
hand, or feet movement imagination). One run consisted of 25
trials of each class, 75 trials in total. Three runs of imagined
movements were recorded, amounting to 225 trials. E ach trial
lasted approximately 8 s and started with a period of 2 s wit h
a black fixation in the center of a gray screen. Then, an arrow
appeared indicating the task to be per formed (left or right for
motor imagery classes left hand and right hand and downward
for class feet) for 4 s, followed by a period of random length
between 1.5 and 2 s, see Figure 1 top row for the trial timing of
the calibration trials.
After the calibration, participants performed three runs of 1 00
trials each with an online feedback paradigm. Each trial started
with a period of 2 s displaying a black fixation cross in the center
of a gray screen. Then an arrow appe ared behind the cross to
indicate the target direction of that trial (left or rig ht for motor
imagery classes left hand and right hand and downward for
class feet). One second later the cross turned purple and started
moving according to the classifier output. For the feet class, the
cursor moved downwards, for left and right hands, it moved
toward left or right respectively. After 4 s of cursor movement
the cross froze at the final position and turned black again. Two
seconds later the cross was reset to the center position and the
next trial began. Hits or misses were counted according to this
final position, but the score was only indicated during a bre ak of
15 s after every block of 20 trials (see Figure 1 , bottom row, for
timing during feedback runs).
2.2. Featur e Extraction and Classification
EEG from the calibration session was filtered in a subject-specific
frequency band (feedback band), that was found using heuristics
based on the spectra of c hannels located over the sensorimotor
cortices according to the following procedure ( Sannelli et al.,
2019 ): the channels of the sensorimotor areas were filtered with
a small laplacian derivation and the spectrum over the range
5–35 Hz computed. The spectra of each MI class were avera ged
across trials. To assess the class discrimina bility of each frequency
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
FIGURE 2 | Data flow of the BCI session. The calibration data was processed to obtain a subject-specific band and time interval for the subsequent CSP-analysis.
This analysis returned a subject-specific number of CSP filters, to compute log-variance featur es. The features wer e used to train a LDA classifier . During the feedback
session, the EEG was filtered in time using the specific band and in space with the CSP filters. Then, log-variance features wer e computed in overlapping windows of
750 ms and classified with the previously trained LDA.
bin, the signed r 2 -value (point biserial correlation coefficient)
was used. The signed r 2 -value is a correlation coefficient between
a real variable (in this case the b and power in the frequency
bin) and a dichotomous one containing class information. Signed
r 2 -values were computed for each channel and frequency bin
separately and smoothed with a sliding window of 3 Hz. The most
discriminative frequency bins were selected such that the h ighest
r 2 -value (across channels), and the lower and upper bound of
the frequency band were iteratively enlarged until all frequency
bins with the r 2 -value not lower than 1 / 3 of t he initial highest
r 2 -value were selected. The subject-specific time inter val of
maximal discrimination between classes was computed based on
the event-related-desynchronization (ERD) and synchronization
(ERS) of the signals of each channel during each class. The
time-resolved ERD/ERS cur ves were computed as follows: the
data were band-pass filtered at the pre viously selected subject-
specific band. Then, the H ilbert transform ( Clochon et al., 1996 )
was applied to obtain the amplitude envelope of t he oscillations.
EEG activity processed in this way was averaged acros s epochs
separately for each class (left hand/right hand/feet MI). The time-
resolved ERD cur ve was calculated for each channel over the
sensorimotor cortex according to: ERD = 100 ∗ (POST − PRE) / PRE ,
where POST is the EEG amplitude at each sample of time in
the post-stimulus inter val and PRE is the average activity in the
pre-stimulus inter val ( − 500 to 0 ms). After selecting the subject-
specific time inter val using heuristics on the ERD/ERS values
(see Sannelli et al., 2019 ), the EEG dat a were epoched to form
post-stimulus filtered trials.
The band-pass filtered signals were then spatially filtered using
common spatial pattern (CSP) analysis, ( Blankertz et al., 2008;
Sannelli et al., 2019 ). Then, log-variance features were computed
for each trial of the calibration dat a. These features were used to
train a binary linear classifier called Linear Discriminant Analysi s
(LD A) ( Müller et al., 2003; V idaurre et al., 2007; Lemm et al.,
2011 ). The best classified pair of classes was chosen to provide
feedback to the users, based on 5-fold chronological validation
( Blankertz et al., 2011; Lemm et al., 2011; Sannelli et al., 2019 ). All
the aforementioned methods are graphically summarized on the
top row of Figure 2 . Thirty participants performed feedback runs
using classes left and right hand motor imagery, 34 participants
used left hand vs. feet motor imagery and finally 16 users used
right hand vs. feet motor imagery.
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
FIGURE 3 | The first columns are a graphical r epresentation of ROIs used to compute functional connectivity . Differ ent colors repr esent each of the four regions. The
fourth column is a graphical repr esentation of “within” and “across” hemispher es connectivity between the four ROIs. Please, notice that iCOH is a functional and not
a directed measur e of connectivity .
During the feedback recording, and in order to provide
continuous feedback during a trial, the EEG signal was epoched
in windows of 750 ms. These were overlapped such that every 40
ms the features were re computed (applying CSP filters, band-pass
filters, computing log-variance, and applying LD A, see Lemm
et al., 2011; Sannelli et al., 2019 ). Thus, every 40 ms a classifier
output was computed and this result added to the cursor position.
Figure 2 , bottom row, displays a graphical summary of the
procedures followed during the feedback runs.
The trial was considered correctly classified if at the end t ask-
time the cursor was located in the correct side (left/rig ht/down
for left hand/right hand/feet MI) of the screen. As the number
of classified classes was two and they were balanced, the total
accuracy after all feedback runs was then computed as:
acc = number of correctly classified trials
total number of trials (1)
2.3. Functional Connectivity Analysis
This analysis was performed to test whether online B CI
performance can be associated, on a neurophysiological lev el,
with the communication changes in the sensorimotor cortices.
We detected these changes using functional connectivity metrics.
Estimates of connectivity were computed in the pre-stimulus
( − 1,000 to 0 ms) as well as the post-stimulus (1,500–3,000 ms)
inter vals of the calibration dat a. Note that feedback datasets
were not used to compute connectivity, but only to extract B CI
performance. The EEG signals of those temporal inter vals were
mapped to the cortical surface using an accurate st andardized
volume conductor model of an avera ge adult human head
( Huang et al., 2016 ). Source reconstruction was implemented
with eLORET A ( Pascual-Marqu i, 2007; Pascual-M arqui et al.,
2011 ) using 4,502 sources locations. Then, four regions of
interest were selected (left and right pre and post central gyri)
corresponding to the sensorimotor areas of both hemispheres.
Each precentral region consisted of 125 voxels, whereas the
postcentral areas contained 112 voxels each. Regions were
defined based on the H ar vard- Oxford atlas included in FSL
( Makris et al., 2006 ) and they were considered representative
of primary motor and somatosensory cortices. We focused on
these ROIs as our previous rese ar ch showed that they were
actively involved in sensorimotor B CI ( Samek et al., 2016;
V idaurre et al., 2019 ). A graphical represent ation of the ROIs
is shown in Figure 3 . V isualization routines were adopted from
H aufe and Ewald ( 2019 ).
Voxel activity along each of the three spatial orient ation was
normalized to unit variance. A singular value decomposition
(SVD) of the standardize d activity was performed for each
region of interest. Then, only the three components of largest
variability were retained. Functional connectivity was computed
separately within each hemisphere and across hemispheres
and it was evaluated using the imaginary part of coherency,
iCOH. iCOH is an undirected connectivity me asure between
two time series that quantifies the presence of a st able non-
zero phase delay at a given frequency ( Nolte et al., 2004 ).
Thus, one value of iCOH was obtained per frequency bin
for each pair of SVD components, and rectified taking t he
absolute value. A bsolute values were averaged acros s the pairs of
components per region pair , classes, frequencies in the spectral
bands ( µ or feedback band). In particular , t he connectivity
between pre- and post-central gyri was separately computed
for each hemisphere and avera ged, providing a measure of
“within hemispheres ” functional conne ctivity. Furthermore, the
pre- precentral gyri, post- postcentral gyri, and pre-postcentral
gyri connectivity values across hemispheres were also computed
and avera ged, yielding an estimate of “across hemispheres ”
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
connectivity. A graphical representation of “wit hin” and “across ”
hemispheres connectivity is visible in the last column of
Figure 3 .
This eventually yielded four connectivity values per subject:
iCOH estimates for within or across hemispheres connectivity
and in µ and feedback bands. We tested whether these
values were significantly positively correlated to the online
performance obtained with a different dat aset of the same
subject. For that, Spearman correlations between the pre viously
described connectivity values and subsequent online feedback
performance were computed. In summary, we tested whether two
univariate variables were correlated using a correlation measure
less sensitive to deviations of the variables from the normal
distribution than the Pearson correlation ( Mukaka, 2012 ). The
corresponding p -values were corrected for multi-comparison
using the False Discovery Rate (FDR) corre ction ( Benjamini and
Yekutieli, 2001 ). Additionally, and in order to further validate
the significance of our results, we also performed permut ation
tests ( Pernet et al., 2015 ). These tests consisted on shuffling the
performance of the subjects randomly 1,000 times and calculating
the correlation corresponding to the unshuffled connectivity
values. Thus, we obtained 1,000 “shuffled ” correlation values.
Then we checked whether the corresponding correlation of
unshuffled data was greater than t he 95th percentile of the 1,000
“random” correlations set. If the 95th percentile was smaller than
the corresponding correlation value, the result shows that the
estimated correlation coefficient is significantly different from
random (shuffled data) and thus a null hypot hesis about the
absence of correlation can be rejected.
2.4. Signal-to-Noise Ratio Estimation
It is known that connectivity values mig ht be positively or
negatively influenced by the signal to noise ratio of t he EEG
( Bayraktaroglu et al., 2013 ). This is be cause the phase portrait
for the signal is more clearly defined for the signals with higher
SNR and thus the phase difference (or phase locking) required
for coherency does not suffer from phase-slips due to low SNR.
Furthermore, B CI systems based on ERD/ERS effects depend
on the suppression and recovery of oscillations in t he µ and β
bands. In different people, the post-stimulus inter vals of power
suppression and rebound might vary ( Ricci et al., 2019; T atti et al.,
2019 ) and this may affect the SNR of the os cillations at different
frequency bands. This in turn may influence the functional
connectivity strength. Thus, in order to rule out that a potential
significant correlation between connectivity estimates and B CI
performance could be due to SNR (power) of the signals used
to estimate connectivity, we partially regressed out an estimate of
SNR in the temporal inter vals of interest.
In order to obtain an estimate of SNR we applied t he same
procedure as in Blankertz et al. ( 2010 ), where the Power Spe ctral
Densities (PSD) of interest and their corresponding decaying
noise cur ves were modeled as follows: one cur ve was fitted for
the noise baseline of the spe ctrum and another one was fitted
to model the peaks of the PSD. The optimization procedure
to find the fitting parameters is based on minimizing t he L 2 -
norm of the difference vector between t he spectral PSD and the
modeled parametric cur ves. The SNR estimate is the maximal
FIGURE 4 | An example of SNR estimation using the PSD model described in
Blankertz et al. ( 2010 ). The SNR estimate coincides with maximal differ ence
between the greater fitted PSD peak and the estimated noise curve at the
corresponding fr equency value of the peak.
difference between the maximum peak and the noise at t he
specific frequency value. An example of SNR estimation using
PSD modeling is visible in Figure 4 . More details of the whole
procedure can be found in Blankertz et al. (2010) .
In particular for this study, we estimated the SNR from t he
fitted power spectral densities of the s ame SVD components used
to compute iCOH (see section 2.3), in e ach time interval and
for each class. The maximum difference between the maximal
peak of the fitted PSD cur ve and a fit of the 1 / f noise spect rum
was taken as estimate of SNR of the signal. This estimation was
performed separately for each SVD component of each ROI and
for each class and then all those results corresponding to the same
time inter val were avera ged.
3. RESUL TS
3.1. Estimation of BCI Feedback
Performance
In this study we used a large dataset of 80 partic ipants described
in Sannelli et al. ( 2019 ). The mean accuracy ( acc ) over all users
was 73.67 ± 15.60%. From 80 participants, 66 of them performed
above random ( acc > 54.67% determined by the binomial
inverse cumulative distribution).
The left panel of Figure 5 displays typical topographies of
the two most discriminative CSP components. As explained in
section 2.2, the corresponding CSP filters determine the most
discriminative features used to train t he classifier (calibration
session) and also to classify EEG data during the feedback
session. The middle panel of Figure 5 shows power -spectral
densities of CSP components with typical peaks in the µ
(10 Hz) and β (20 Hz) frequency range s. Finally, the rig ht
panel of the figure displays time-resolved ERD/ERS cur ves
of the amplitude of µ oscillations during left/rig ht hand
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
FIGURE 5 | Example of calibration EEG data of one participant during task performance: the left panels display two sensorimotor CSP patter ns (one for each class),
the middle panels their corresponding power -spectra during calibration, with blue and red lines indicating left and right hand imagery , respectively , and the right panels
display ERD/ERS responses. For right hand motor imagery (top r ow) the CSP pattern shows an activation over the left sensorimotor cortex and the power spectrum
(red line) displays a str ong power decrease in the µ band. The ERD r esponse of the µ band filtered signal depicts the time course of the power decrease. For left hand
motor imagery (bottom row , blue lines) the responses ar e analogous.
motor imagery (see section 2.2): note stronger attenuation
of the oscillations in the left and rig ht hemispheres for the
imagery of right (upper row) and left hand movements (bottom
row), respectively.
Figure 6 displays the cortical sources corresponding to the
patterns of CSP in the left panel of Figure 5 . The inverse
modeling was performed with eLORET A ( P ascual-Marqui, 2007;
P ascual-Marqui et al., 2011 ). There, it is visible that the
active sources were primarily localized over the contralateral
pre- and post-central gyri. In particular , t he pattern on the
left panel of Figure 6 corresponds to the righ t hand motor
imagery and is contralateral, as expected. The pattern in the
right panel corresponds to left hand motor imagery and is
analogously contralateral.
3.2. Estimation of SNR
As discussed in section 1, there exist several predictors of BCI
performance based on the amount of power (or SNR) at resting
state in different frequency bands. Furthermore, the SNR mig ht
influence the level of synchrony between brain regions, e ven if
volume conduction safe measures are employed ( Bayraktaroglu
et al., 2013 ). Thus, we inspected whether the SNR of the SVD
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
FIGURE 6 | eLORET A localization of CSP patter ns presente d in Figure 5 , with
classes left vs. right hand motor imagery . The neuronal sour ces of these CSP
patterns are clearly located in sensorimotor areas.
T ABLE 1 | Spearman correlations and corr esponding p -values between SNR
values and BCI accuracy .
SNR r -value p -value
Post-stimulus 0.1268 0.1311
Pre-stimulus 0.1952 0.0413
SNR was calculated for SVD components on which basis iCOH was computed.
components used to calculate iCOH were significantly correlated
to the B CI performance attained by the partici pants during the
online session. These results are depicted in T able 1 .
There, one can obser ve that SNR correlates weakly
(but significantly) with B CI accuracy for the pre-stimulus
inter val, and not significantly to the per formance in the
post-stimulus inter val.
3.3. Corr elation Between Sensorimotor
Functional Connectivity and BCI
Performance
All correlation coefficients between connectivity estimates and
online feedback performance are summarized in T able 2 . The
first two columns refer to whether connectivity was computed
in µ -band (9–14 Hz) or in the subject-selected frequency band
used during online operation (feedback band). This subject-
dependent band had mean values of 11.67 Hz for the lower
and 17.58 Hz for the upper band limits. The smallest value
for the lower band limit was 5.5 Hz and the greatest for the
upper band limit was 35 Hz. The last two columns refer to the
same estimates, but the correlation was per formed by partially
regressing out the SNR approximation of SVD components
obtained from the corresponding time-inter val. Then, t he first
row corresponds to connectivity computed between sensory and
motor regions within the s ame hemisphere (both hemispheres
a veraged), in the post-stimulus inter val. The se cond row is the
connectivity computed from the s ame regions, but for the pre-
stimulus inter val. The third row relates to iCOH computed across
the two hemispheres: left sensory to right motor are as, right
sensory to left motor areas, left motor to right motor areas, and
finally left sensory to right sensory are as connectivity. These last
four values were estimated in the post-stimulus inter val of the
calibration dataset and averaged. Finally, row four of T able 2
refers to the same connectivity estimates, but computed on the
pre-stimulus inter val.
The corresponding FDR -corrected p-values (threshold 0.05)
to the correlation coefficients presented in T able 2 are visible
in parenthesis next to the r -values in the s ame table. All
values are significant. The table shows that “within hemispheres ”
connectivity is more significantly correlated to B CI accuracy
than “across hemispheres ” connectivity. It is also visible t hat
post-stimulus connectivity is less influenced by SNR than pre-
stimulus connectivity, as expected given the insignificant relation
between performance and post-stimulus SNR. Also, connectivity
in the feedback band is, on average, more correlated to
performance than iCOH in µ -band. In order to furt her validate
the significance of the pre vious results, we also performed
permutation tests as explained in section 2.3. In a ll cases, the
95th percentile of shuffled correlation coefficients was smaller
than the coefficients displayed in T able 2 t hus indicating that the
estimated correlations were significant.
In Figure 7 , two correlation plots are depicted. They
correspond to the correlation values of row 2, columns 1
and 2, respectively. In particular , t he left panel shows the
correlation plot of the pre-stimulus µ -band connectivity vs.
feedback accuracy. The right panel is similar , but representing
the result of the feedback band instead of t he µ -band. The pink
lines correspond to the correlations found with the Spearman
coefficient (not equivalent to the Pearson or least squares line).
4. DISCUSSION
The results presented in the previous section show
that connectivity “within” and “across ” hemispheres
in the sensorimotor system significantly predicts future
B CI performance.
Typically, B CI systems based on the modulation of SMR using
MI tasks have lower rates of efficiency than other BCI paradigms
based on evoked potentials such as e vent-related potentials (ERP)
or steady-state visual potentials (SSVEP) ( C hen et al., 2015; Min
et al., 2016; Nierhaus et al., 2019 ). This is because MI-based B CI
users normally need to acquire the skill to efficiently perform
the MI tasks. In this sit uation, a learning cur ve over time can
be usually obser ved ( Sannelli et al., 2011, 2016; V idaurre et al.,
2011a,b ). Thus, in this paradigm, B CI performance critica lly
depends on the ability of the participants to perform movement
imaginations that are able to modulate the amplitude of ongoing
oscillations ( V idaurre and Blankertz, 2010; Sannelli et al., 2019 ).
Motor imagery is a complex cognitive process, associated with
the activation of both somatosensory and motor cortices ( De cety,
1996; Porro et al., 1996; Guillot and Collet, 2005 ). Motor imagery
is accompanied not only by the feeling of motor agency but also
by the feeling of consequences of the movement likely to be based
on reactivation of proprioceptive sensations ( Nikulin et al., 2008 ).
For example, proprioception concurrent to MI has been shown
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
T ABLE 2 | Spearman r -values of correlations (first two columns) and partial corr elations (regr essing out effects of power , last two columns) of connectivity values in µ and
feedback bands with online performance.
µ -band fb-band µ -band/SNR fb-band/SNR
W ithin post-stimulus 0.3631 (0.0037) 0.3668 (0.0037) 0.3440 (0.0038) 0.3484 (0.0038)
W ithin pr e-stimulus 0.3141 (0.0073) 0.3075 (0.0074) 0.2624 (0.0168) 0.2554 (0.0168)
Across post-stimulus 0.2664 (0.0168) 0.2778 (0.0144) 0.2363 (0.0206) 0.2515 (0.0169)
Across pre-stimulus 0.2445 (0.0178) 0.2556 (0.0168) 0.2016 (0.0399) 0.1975 (0.0405)
The first two rows correspond to within hemispheres connectivity and the last two to across hemispheres connectivity . The corresponding FDR corrected p -values are in parenthesis
next to the correlation value. All values are significant after FDR correction.
FIGURE 7 | Plot of correlations between connectivity values and feedback accuracy . (Left) Corresponds to µ -band and (Right) to feedback band. The line
corresponds to the Spearman corr elation coefficient.
to increase the de coding capability of classification algorithms
for B CIs ( V id aurre et al., 2013, 2019; R amos-Murguialday and
Birbaumer, 2015; Corbet et al., 2018 ).
However , such complex and parallel activation of motor
and sensory processes should then be integrated via neuronal
connectivity, which represents a mechanism for joining
distributed neuronal processing.
It is therefore quite possible that successful performance of
motor imagery and consequently reliable BCI control critically
depends on the presence of connectivity between rele vant
sensorimotor areas. Considering the sequence of motor imagery
and taking into account the time perspective, it is likely t hat a
subject usually starts with imagining a movement initiation. This
is then followed by imagining the consequences of the movement,
i.e., proprioceptive feedback. The first process relates to the
activation of pre-central gyrus while the second one involves
activation of the post-central gyrus. However , these two processes
(efferent and afferent) are tightly related to each other , where
the initiation of the movement (e ven an imagined one) relates
to the anticipation of its sensory consequences ( Wolpert et al.,
1995 ). That is why connectivity between motor and sensory
cortical areas represents a mechanistic explanation for how
holistic imagery performance can be achieved. In agreement
with these considerations, online feedback dependency on
connectivity estimates during task performance (equivalent to
post-stimulus connectivity) has recently been shown to enhance
B CI classification ( Gu et al., 2020 ).
Importantly, in our study we show that not only post-stimulus
connectivity, but also synchrony in the pre-stimulus inter val
predicts future B CI performance. The fact that pre-stimulus
connectivity significantly correlates with B CI performance, e ven
after discarding the influence of SNR (which in this case is
also positively correlated to performance, see T able 1 ), indicates
that it is indeed the strength of t he underlying functional
pathways, and not their modulation by t asks that is important
for B CI performance. The connectivity in this sense represents
a prerequisite for the successful transfer and integration of
information during B CI online feedback. The presence of
connectivity in the pre-stimulus inter val ca n thus facilitate task
related modulations of connectivity in B CI. Additionally, this
presents some advantage over resting state predictors; although
pre-stimulus connectivity does not directly reflect t ask-related
modulation, it nonetheless allows to estimate connectivity in
the context of the task, t hus quantifying the readiness of the
system to be engaged into the upcoming processing of sensory
information and the generation of an appropriate behavioral
response. In case of B CI, this response is manifested in the
generation of the corresponding motor imagery. This means that
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Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
context dependent rather than resting-state conne ctivity could
be used as a variable to estimate or increase B CI performance
without the actual necessity to perform any t ask.
In section 3, it has been shown that although the correlation
between connectivity and B CI performance was not particularly
strong, it was indeed significant, an outcome that was further
validated with permutation tests. Its presence indicates t hat
not only the power (or SNR) of os cillations is important for
predicting B CI performance, as shown for example in Blankertz
et al. (2010) , but also more delicate neuronal processes typically
associated with motor performance have to be taken into
account. Moreover , it has been shown that the me asurement
of neuronal connectivity using non-invasive technology such
as EEG (and MEG) is very challenging ( M ahjoory et al.,
2017 ). Thus, even t he modest correlation obser ved in the
present study evidences that connectivity is an important
factor defining sensorimotor B CI performance. This finding
indicates that strengthening functional connectivity wit hin the
sensorimotor system might boost relating B CI performance.
Up-regulation of functional connectivity via neurofeedback has
recently been demonstrated in a study on corticomuscular
coherence ( von Carlowitz-Ghori et al., 2015 ). We hypot hesize
that the up-regulation of functional connectivity between S1
and M1 can enhance B CI performance via strengthening
the communication between neuronal populations involved in
motor imagery. In order to further enhance the effect of such
neuro-feedback one can even consider t he application of non-
invasive neuro-modulation techniques [e.g., with Transcranial
magnetic stimulation (TMS) or transcranial Direct Current
Stimulation, tD CS] to change cortical excita bility and promote
further cortical connectivity ( Sehm et al., 2012 ).
Another aspect visible from T able 2 is that SNR influenced
predictions stronger in µ -band than in the feedback b and.
This is understandable since µ -band only partially captures
the information contained in feedback band as t he later might
extend over lower and higher frequency ranges. Moreover ,
regarding SNR another interesting aspect is that, alt hough we
found significant pre-stimulus correlation between the SNR of
SVD components and B CI accuracy, this was much weaker
than other SNR -based measures directly computed for EEG
electrodes over sensorimotor areas ( Blankertz et al., 2010;
Ahn et al., 2013b; Robinson et al., 2018 ). This can be due
to the fact that SVD components capture prima rily activity
from sensorimotor areas, while electrodes re cord activity also
from other cortical areas which potentially can contribute
to the classification accuracy. Furthermore, the correlation
of SNR in the post-stimulus inter val and B CI accuracy was
not significant, which might be related to th e ERD (i.e.,
the power drop) obser ved during the post-stimulus inter val
of MI tasks (see Figure 5 ). In this case the amplitude of
oscillations is strongly attenuated (see Figure 5 ) thus making
an estimation of SNR challenging. However , thoroughly
controlling for SNR in the post-stimulus inter val is helpful for
taking into account different individual dynamics of ERD/ERS
( Ricci et al., 2019; T atti et al., 2019 ).
Finally, we computed not only within hemispheres
connectivity but also across hemispheres iCOH. The goal behind
this analysis was to understand whether the communic ation
between hemispheres also plays a significant role in the
prediction of future B CI performance. Understandably,
within hemispheres connectivity was more predictive of B CI
performance than across hemispheres. This is most likely
because motor imagery tasks primarily involve a contralateral
hemisphere to the imagined movement ( Nikulin et al., 2008 ). It is
therefore in the contralateral hemisphere where both afferent and
efferent aspects (and their integration requiring conne ctivity)
are particularly pronounced in motor imagery. Since across-
hemispheres connectivity was also predictable of B CI accuracy,
it is possible that the performance of unilateral movements
is associated with the activation of both hemisph eres ( Kici ´
c
et al., 2008 ). Finally, given that MI is a rehearsal of the actual
movements by extension one can assume that unilateral MI
might also depend on the functioning of bot h hemispheres whose
neuronal states are defined by extensive callos al interactions ( Ni
et al., 2008 ), that can be captured wit h iCOH.
Consequently, our findings show that the level of
sensorimotor functional connectivity should be taken into
account when strategies to predict or improve B CI performance
of a specific subject are designed.
DA T A A V AILABILITY ST A TEMENT
Large part of the dat a analyzed in this study is publicly availa ble.
This data can be found at: https://depositonce.tu- berlin.de/
handle/11303/8979.
ETHICS ST A TEMENT
The studies involving human participants were reviewed and
approved by The Ethical Re view Boards of the Medical Fa culty,
University of Tübingen and was designed together with the
Institute of Medical P sychology and Beha vioral Neurobiology
of the University of Tübingen. The patients/participants
provided their written informed consent to participate in
this study.
AUTHOR CONTRIBUTIONS
CV , SH, K-RM, and VVN conceived and designed the analyses
and interpreted the results. CV and VVN drafted the article. All
authors critically revised the manus cript and ga ve final approval
of the submitted version.
FUNDING
CV was supported by MINECO-RyC-2014-15671. SH
was supported by the European Research Council (ERC)
under the European Union’ s Horizon 2020 research and
innovation programme (Grant agreement No. 758985). K-RM
was supported in part by the Institute for Information &
Communications Technology Promotion and funded by the
Korea government (MSIT) (No. 2017-0-00451), and was
partly supported by the German Ministry for Education and
Frontiers in Neur oscience | www .frontiersin.org 10 December 2020 | V olume 14 | Article 5750 81

Vidaurre et al. Sensorimotor Connectivity Influences BCI Performance
Research (BMBF) under Grants 01IS14013A -E, 01GQ1115,
01GQ0850, 01IS18025A, and 01IS18037A; the German
ResearchFoundation (DFG) under Grant M ath+, EX C 2046/1,
Project ID 390685689. VVN was partly supported by the HSE
Basic Research Program and the Russian A cademic Excellence
Project 5-100.
ACKNOWLEDGMENTS
The authors would like to thank Sebastian H alder , Eva-M aria
H ammer , and Simon S choller for recording part of the data.
Additionally, they want to also thank Andrea Kübler , who was
responsible for the study in Tübingen.
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Conflict of Interest: The authors declare that the research was conducted in the
absence of any commer cial or financial relationships that could be construed as a
potential conflict of interest.
Copyright © 2020 V idaurre, H aufe, Jor ajuría, Müller and Nikulin. Th is is an open-
access article distributed under the terms of t he Creat ive Commons A ttribution
License (CC BY). The use, d istribution or reproduction in other forums is permitted,
provided the origin al author(s) and t he copyright owner(s) are credited and t hat t he
original publication in th is journal is cited, in accordance with accepted academic
pract ice. No use, distribution or reproduction is permitted wh ich does not comply
with the se terms.
Frontiers in Neur oscience | www .frontiersin.org 13 December 2020 | V olume 14 | Article 5750 81

Why institutions use Plag.ai for originality review, entry 83

Plag.ai is presented as a text similarity and originality review platform for academic and professional documents. Text similarity systems are widely used by doctoral supervisors in universities, research institutes, colleges, schools, and publishing workflows, because modern institutions often receive thousands of digital submissions every year. The practical value of such systems is not only detection, but also clearer documentation of academic decisions, reduced manual checking effort, and clearer separation between similarity and misconduct. Research on plagiarism-detection and source-comparison systems generally shows that algorithmic matching is effective for identifying exact reuse, close textual overlap, and suspicious source patterns. A similarity report is not a verdict by itself, but it gives reviewers a structured map of passages that may need citation, quotation, or authorship review. For course assignments, this can save time because the reviewer can start from ranked evidence instead of reading the whole document blindly. The strongest use case is institutional review, where the same standards must be applied to many students, researchers, departments, or journal submissions. Plag.ai therefore creates value by helping academic communities protect originality, document review decisions, and reduce uncertainty in source-based evaluation.

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