6533b7d9fe1ef96bd126c1ad
RESEARCH PRODUCT
Exploring Frequency-Dependent Brain Networks from Ongoing EEG Using Spatial ICA During Music Listening
Chi ZhangMinna HuotilainenTapani RistaniemiFengyu CongFengyu CongYongjie ZhuKlaus MathiakPetri ToiviainenHanna Poikonensubject
DYNAMICS6162 Cognitive scienceBrain activity and meditationComputer scienceSpeech recognitionIndependent components analysisElectroencephalographyACTIVATIONSuperior temporal gyrus0302 clinical medicineMusic information retrievalaivotutkimusEEGindependent components analysisBrain MappingRadiological and Ultrasound Technologymedicine.diagnostic_test05 social sciencesBrainElectroencephalographyhumanitiesEMOTIONSNeurologyFeature (computer vision)Auditory PerceptionALPHA-BANDFrequency-specific networks; Music information retrieval; EEG; Independent components analysisfrequency-specific networksAnatomyaivotTOOLBOX515 PsychologyMusic information retrievalmusic information retrievalmusiikkibehavioral disciplines and activitieskuunteleminen050105 experimental psychologyTIMBRE03 medical and health sciencesOSCILLATIONSmedicineHumans0501 psychology and cognitive sciencesRadiology Nuclear Medicine and imagingPERCEPTIONOriginal PaperATTENTIONtaajuusMagnetoencephalographyaivokuoriFrequency-specific networksNeurology (clinical)Functional magnetic resonance imaginghuman activitiesTimbreMusic030217 neurology & neurosurgeryRESPONSESdescription
Recently, exploring brain activity based on functional networks during naturalistic stimuli especially music and video represents an attractive challenge because of the low signal-to-noise ratio in collected brain data. Although most efforts focusing on exploring the listening brain have been made through functional magnetic resonance imaging (fMRI), sensor-level electro- or magnetoencephalography (EEG/MEG) technique, little is known about how neural rhythms are involved in the brain network activity under naturalistic stimuli. This study exploited cortical oscillations through analysis of ongoing EEG and musical feature during freely listening to music. We used a data-driven method that combined music information retrieval with spatial Fourier Independent Components Analysis (spatial Fourier–ICA) to probe the interplay between the spatial profiles and the spectral patterns of the brain network emerging from music listening. Correlation analysis was performed between time courses of brain networks extracted from EEG data and musical feature time series extracted from music stimuli to derive the musical feature related oscillatory patterns in the listening brain. We found brain networks of musical feature processing were frequency-dependent. Musical feature time series, especially fluctuation centroid and key feature, were associated with an increased beta activation in the bilateral superior temporal gyrus. An increased alpha oscillation in the bilateral occipital cortex emerged during music listening, which was consistent with alpha functional suppression hypothesis in task-irrelevant regions. We also observed an increased delta–beta oscillatory activity in the prefrontal cortex associated with musical feature processing. In addition to these findings, the proposed method seems valuable for characterizing the large-scale frequency-dependent brain activity engaged in musical feature processing.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-05-01 | Brain Topography |