Development of the Complex General Linear Model in the Fourier Domain : Application to fMRI Multiple Input-Output Evoked Responses for Single Subjects

• Published in: Computational and mathematical methods in medicine Vol. 2013; no. 2013; pp. 1 - 16
• Main Authors: Rio, Daniel E., Rawlings, Robert R., Woltz, Lawrence A., Gilman, Jodi, Hommer, Daniel W.
• Format: Journal Article
• Language: English
• Published: Cairo, Egypt Hindawi Puplishing Corporation 01.01.2013; Hindawi Publishing Corporation
• Subjects: Alcoholism - blood; Alcoholism - physiopathology; Brain - physiology; Computational Biology; Evoked Potentials, Visual; Fourier Analysis; Hemodynamics; Humans; Image Interpretation, Computer-Assisted; Linear Models; Magnetic Resonance Imaging - statistics & numerical data; Models, Neurological; Multivariate Analysis; Oxygen - blood; Signal-To-Noise Ratio; Statistics, Nonparametric
• ISSN: 1748-670X; 1748-6718; 1748-6718
• DOI: 10.1155/2013/645043

A linear time-invariant model based on statistical time series analysis in the Fourier domain for single subjects is further developed and applied to functional MRI (fMRI) blood-oxygen level-dependent (BOLD) multivariate data. This methodology was originally developed to analyze multiple stimulus input evoked response BOLD data. However, to analyze clinical data generated using a repeated measures experimental design, the model has been extended to handle multivariate time series data and demonstrated on control and alcoholic subjects taken from data previously analyzed in the temporal domain. Analysis of BOLD data is typically carried out in the time domain where the data has a high temporal correlation. These analyses generally employ parametric models of the hemodynamic response function (HRF) where prewhitening of the data is attempted using autoregressive (AR) models for the noise. However, this data can be analyzed in the Fourier domain. Here, assumptions made on the noise structure are less restrictive, and hypothesis tests can be constructed based on voxel-specific nonparametric estimates of the hemodynamic transfer function (HRF in the Fourier domain). This is especially important for experimental designs involving multiple states (either stimulus or drug induced) that may alter the form of the response function.