Automatic detection of noisy channels in fNIRS signal based on correlation analysis

BACKGROUND fNIRS signals can be contaminated by distinct sources of noise. While most of the noise can be corrected using digital filters, optimized experimental paradigms or pre-processing methods, few approaches focus on the automatic detection of noisy channels. METHODS In the present study, we propose a new method that detect automatically noisy fNIRS channels by combining the global correlations of the signal obtained from sliding windows (Cui et al., 2010) with correlation coefficients extracted experimental conditions defined by triggers. RESULTS The validity of the method was evaluated on test data from 17 participants, for a total of 16 NIRS channels per subject, positioned over frontal, dorsolateral prefrontal, parietal and occipital areas. Additionally, the detection of noisy channels was tested in the context of different levels of cognitive requirement in a working memory N-back paradigm. COMPARISON WITH EXISTING METHOD(S) Bad channels detection accuracy, defined as the proportion of bad NIRS channels correctly detected among the total number of channels examined, was close to 91%. Under different cognitive conditions the area under the Receiver Operating Curve (AUC) increased from 60.5% (global correlations) to 91.2% (local correlations). CONCLUSIONS Our results show that global correlations are insufficient for detecting potentially noisy channels when the whole data signal is included in the analysis. In contrast, adding specific local information inherent to the experimental paradigm (e.g., cognitive conditions in a block or event-related design), improved detection performance for noisy channels. Also, we show that automated fNIRS channel detection can be achieved with high accuracy at low computational cost.

[1]  Meltem Izzetoglu,et al.  Motion artifact cancellation in NIR spectroscopy using discrete Kalman filtering , 2010, Biomedical engineering online.

[2]  D. Boas,et al.  HomER: a review of time-series analysis methods for near-infrared spectroscopy of the brain. , 2009, Applied optics.

[3]  Y. Hoshi Functional near-infrared spectroscopy: potential and limitations in neuroimaging studies. , 2005, International review of neurobiology.

[4]  Kathryn M. McMillan,et al.  N‐back working memory paradigm: A meta‐analysis of normative functional neuroimaging studies , 2005, Human brain mapping.

[5]  Marco Ferrari,et al.  A brief review on the history of human functional near-infrared spectroscopy (fNIRS) development and fields of application , 2012, NeuroImage.

[6]  Hellmuth Obrig,et al.  A wearable multi-channel fNIRS system for brain imaging in freely moving subjects , 2014, NeuroImage.

[7]  David A. Boas,et al.  A Systematic Comparison of Motion Artifact Correction Techniques for Functional Near-Infrared Spectroscopy , 2012, Front. Neurosci..

[8]  Clare E Elwell,et al.  Automatic detection of motion artifacts in infant functional optical topography studies. , 2010, Advances in experimental medicine and biology.

[9]  Yoko Hoshi,et al.  Functional near-infrared spectroscopy: current status and future prospects. , 2007, Journal of biomedical optics.

[10]  David A. Boas,et al.  Motion artifacts in functional near-infrared spectroscopy: A comparison of motion correction techniques applied to real cognitive data , 2014, NeuroImage.

[11]  Tania S. Douglas,et al.  Motion Artifact Removal for Functional Near Infrared Spectroscopy: A Comparison of Methods , 2010, IEEE Transactions on Biomedical Engineering.

[12]  Tomás Ward,et al.  Artifact Removal in Physiological Signals—Practices and Possibilities , 2012, IEEE Transactions on Information Technology in Biomedicine.

[13]  Y. Benjamini,et al.  Controlling the false discovery rate: a practical and powerful approach to multiple testing , 1995 .

[14]  Toshinori Kato,et al.  Paradoxical correlation between signal in functional magnetic resonance imaging and deoxygenated haemoglobin content in capillaries: a new theoretical explanation , 2002 .

[15]  Phillip Wolff,et al.  Causal reasoning with forces , 2015, Front. Hum. Neurosci..

[16]  Meltem Izzetoglu,et al.  Motion artifact cancellation in NIR spectroscopy using Wiener filtering , 2005, IEEE Transactions on Biomedical Engineering.

[17]  Zhen Yuan,et al.  Fusion of fNIRS and fMRI data: identifying when and where hemodynamic signals are changing in human brains , 2013, Front. Hum. Neurosci..

[18]  Agostino Di Ciaccio,et al.  Computational Statistics and Data Analysis Measuring the Prediction Error. a Comparison of Cross-validation, Bootstrap and Covariance Penalty Methods , 2022 .

[19]  Anders M. Dale,et al.  Diffuse optical imaging of brain activation: approaches to optimizing image sensitivity, resolution, and accuracy , 2004, NeuroImage.

[20]  T. Monk The post-lunch dip in performance. , 2005, Clinics in sports medicine.

[21]  C. Vaidya,et al.  Sensitivity of fNIRS to cognitive state and load , 2014, Front. Hum. Neurosci..

[22]  A. Villringer,et al.  Non-invasive optical spectroscopy and imaging of human brain function , 1997, Trends in Neurosciences.

[23]  Hasan Ayaz,et al.  A Methodology for Validating Artifact Removal Techniques for Physiological Signals , 2012, IEEE Transactions on Information Technology in Biomedicine.

[24]  Xu Cui,et al.  Functional near infrared spectroscopy (NIRS) signal improvement based on negative correlation between oxygenated and deoxygenated hemoglobin dynamics , 2010, NeuroImage.

[25]  S. Arridge,et al.  Estimation of optical pathlength through tissue from direct time of flight measurement , 1988 .

[26]  Hideki Takahashi,et al.  Correlation of prefrontal cortical activation with changing vehicle speeds in actual driving: a vector-based functional near-infrared spectroscopy study , 2013, Front. Hum. Neurosci..

[27]  Hang Zhang,et al.  Ubiquitous Log Odds: A Common Representation of Probability and Frequency Distortion in Perception, Action, and Cognition , 2012, Front. Neurosci..

[28]  M. Ferrari,et al.  The use of near infrared spectroscopy in sports medicine. , 2003, The Journal of sports medicine and physical fitness.

[29]  P. Enticott,et al.  The neural underpinnings of vicarious experience , 2014, Front. Hum. Neurosci..

[30]  David A Boas,et al.  Eigenvector-based spatial filtering for reduction of physiological interference in diffuse optical imaging. , 2005, Journal of biomedical optics.

[31]  Naoki Tanaka,et al.  Wavelet analysis for detecting body-movement artifacts in optical topography signals , 2006, NeuroImage.

[32]  Terry M. Peters,et al.  3D statistical neuroanatomical models from 305 MRI volumes , 1993, 1993 IEEE Conference Record Nuclear Science Symposium and Medical Imaging Conference.

[33]  David G. Stork,et al.  Pattern Classification , 1973 .

[34]  Robert Riener,et al.  Physiological noise cancellation in fNIRS using an adaptive filter based on mutual information , 2014, 2014 IEEE International Conference on Systems, Man, and Cybernetics (SMC).

[35]  S. Swinnen,et al.  Topological correlations of structural and functional networks in patients with traumatic brain injury , 2013, Front. Hum. Neurosci..

[36]  Monica Fabiani,et al.  A kurtosis-based wavelet algorithm for motion artifact correction of fNIRS data , 2015, NeuroImage.

[37]  Ardalan Aarabi,et al.  Autoregressive model based algorithm for correcting motion and serially correlated errors in fNIRS. , 2013, Biomedical optics express.

[38]  Seán F. McLoone,et al.  The Use of Ensemble Empirical Mode Decomposition With Canonical Correlation Analysis as a Novel Artifact Removal Technique , 2013, IEEE Transactions on Biomedical Engineering.

[39]  D H Brainard,et al.  The Psychophysics Toolbox. , 1997, Spatial vision.

[40]  Keum-Shik Hong,et al.  fNIRS-based brain-computer interfaces: a review , 2015, Front. Hum. Neurosci..

[41]  Tom Fawcett,et al.  An introduction to ROC analysis , 2006, Pattern Recognit. Lett..

[42]  Tanja Schultz,et al.  Mental workload during n-back task—quantified in the prefrontal cortex using fNIRS , 2014, Front. Hum. Neurosci..

[43]  Rangaraj M. Rangayyan,et al.  Biomedical Signal Analysis: A Case-Study Approach , 2001 .

[44]  W. Kirchner Age differences in short-term retention of rapidly changing information. , 1958, Journal of experimental psychology.