Litcius/Paper detail

Optimizing EEG ICA decomposition with data cleaning in stationary and mobile experiments

Marius Klug, T. Berg, Klaus Gramann

2024Scientific Reports37 citationsDOIOpen Access PDF

Abstract

Electroencephalography (EEG) studies increasingly utilize more mobile experimental protocols, leading to more and stronger artifacts in the recorded data. Independent Component Analysis (ICA) is commonly used to remove these artifacts. It is standard practice to remove artifactual samples before ICA to improve the decomposition, for example using automatic tools such as the sample rejection option of the AMICA algorithm. However, the effects of movement intensity and the strength of automatic sample rejection on ICA decomposition have not been systematically evaluated. We conducted AMICA decompositions on eight open-access datasets with varying degrees of motion intensity using varying sample rejection criteria. We evaluated decomposition quality using mutual information of the components, the proportion of brain, muscle, and 'other' components, residual variance, and an exemplary signal-to-noise ratio. Within individual studies, increased movement significantly decreased decomposition quality, though this effect was not found across different studies. Cleaning strength significantly improved the decomposition, but the effect was smaller than expected. Our results suggest that the AMICA algorithm is robust even with limited data cleaning. Moderate cleaning, such as 5 to 10 iterations of the AMICA sample rejection, is likely to improve the decomposition of most datasets, regardless of motion intensity.

Topics & Concepts

ElectroencephalographyIndependent component analysisDecompositionComputer scienceSIGNAL (programming language)Noise (video)Pattern recognition (psychology)Sample (material)Artificial intelligenceIntensity (physics)Sample size determinationStatisticsMathematicsPsychologyChemistryChromatographyPhysicsPsychiatryProgramming languageQuantum mechanicsImage (mathematics)Organic chemistryEEG and Brain-Computer InterfacesBlind Source Separation TechniquesNeural dynamics and brain function