Functional near infrared spectroscopy (fNIRS) is a neuroimaging technique that allows to monitor the functional hemoglobin oscillations related to cortical activity. One of the main issues related to fNIRS applications is the motion artefact removal, since a corrupted physiological signal is not correctly indicative of the underlying biological process. A novel procedure for motion artifact correction for fNIRS signals based on wavelet transform and video tracking developed for infrared thermography (IRT) is presented. In detail, fNIRS and IRT were concurrently recorded and the optodes’ movement was estimated employing a video tracking procedure developed for IRT recordings. The wavelet transform of the fNIRS signal and of the optodes’ movement, togeth-er with their wavelet coherence, were computed. Then, the inverse wavelet transform was evaluated for the fNIRS signal excluding the frequency content corresponding to the optdes’ movement and to the coherence in the epochs where they were higher with respect to an established thresh-old. The method was tested using simulated functional hemodynamic responses added to real resting‐state fNIRS recordings corrupted by movement artifacts. The results demonstrated the ef-fectiveness of the procedure in eliminating noise, producing results with higher signal to noise ra-tio with respect to another validated method.

A Motion Artifact Correction Procedure for fNIRS Signals Based on Wavelet Transform and Infrared Thermography Video Tracking

Perpetuini D.
Co-primo
;
Cardone D.
Co-primo
;
Filippini C.
Secondo
;
Chiarelli A. M.
Penultimo
;
Merla A.
Ultimo
2021-01-01

Abstract

Functional near infrared spectroscopy (fNIRS) is a neuroimaging technique that allows to monitor the functional hemoglobin oscillations related to cortical activity. One of the main issues related to fNIRS applications is the motion artefact removal, since a corrupted physiological signal is not correctly indicative of the underlying biological process. A novel procedure for motion artifact correction for fNIRS signals based on wavelet transform and video tracking developed for infrared thermography (IRT) is presented. In detail, fNIRS and IRT were concurrently recorded and the optodes’ movement was estimated employing a video tracking procedure developed for IRT recordings. The wavelet transform of the fNIRS signal and of the optodes’ movement, togeth-er with their wavelet coherence, were computed. Then, the inverse wavelet transform was evaluated for the fNIRS signal excluding the frequency content corresponding to the optdes’ movement and to the coherence in the epochs where they were higher with respect to an established thresh-old. The method was tested using simulated functional hemodynamic responses added to real resting‐state fNIRS recordings corrupted by movement artifacts. The results demonstrated the ef-fectiveness of the procedure in eliminating noise, producing results with higher signal to noise ra-tio with respect to another validated method.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11564/755804
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