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| Application of fMRI Activation Area Adaptive Extraction Based on Temporal SelfCorrelation Method of ICA |
Institute of Biomedical and Electromagnetic Engineering, Shenyang University of Technology, Shenyang 110870, China
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Abstract The traditional ICA based activation zone detection is to analyze the correlation between the separated independent component and the reference signal. However, in practical problems, since the differences among the hemodynamic responses of the cerebral regions, the standard reference signal is often not available. Aiming at such problems, in this paper, the method of temporal selfcorrelation (TSC) combined with infomaxICA was proposed. This method processed fMRI data point by point with 5adjacent voxels based ICA, then detected the correlation between each time series period with temporal selfcorrelation algorithm and selected the maximum autocorrelation coefficient as the signal value of the voxel. After that we conversed correlation coefficient distribution to Z distribution which obey N (0, 1) by Ztransform, extracted the active regions with significant difference (a=0.05) in the statistical parametric mapping. The algorithm was applied to deal with simulation data and 12 set of real fMRI data of fist movement with both hands. Results: The method can accurately extract the active region of the simulation data. For real data processing, results of this method have a high similarity with GLM method in the spatial domain (0.465 3±0.136 8 vs 0.490 5±0.134 1) and better than GLM method in the temporal domain (0.636 4±0.011 1 vs 0.369 2±0.010 9). These results have statistical significant. Experimental results showed that, this method has good capacities of detection of functional brain activation areas and spatial orientation.
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