Single-Trial Variability in Event-Related BOLD Signals

Most current analysis methods for fMRI data assume a priori knowledge of the time course of the hemodynamic response (HR) to experimental stimuli or events in brain areas of interest. In addition, they typically assume homogeneity of both the HR and the non-HR "noise" signals, both across brain regions and across similar experimental events. When HRs vary unpredictably, from area to area or from trial to trial, an alternative approach is needed. Here, we use Infomax independent component analysis (ICA) to detect and visualize variations in single-trial HRs in event-related fMRI data. Six subjects participated in four fMRI sessions each in which ten bursts of 8-Hz flickering-checkerboard stimulation were presented for 0.5-s (short) or 3-s (long) durations at 30-s intervals. Five axial slices were acquired by a Bruker 3-T magnetic resonance imager at interscan intervals of 500 ms (TR). ICA decomposition of the resulting blood oxygenation level-dependent (BOLD) data from each session produced an independent component active in primary visual cortex (V1) and, in several sessions, another active in medial temporal cortex (MT/V5). Visualizing sets of BOLD response epochs with novel BOLD-image plots demonstrated that component HRs varied substantially and often systematically across trials as well as across sessions, subjects, and brain areas. Contrary to expectation, in four of the six subjects the V1 component HR contained two positive peaks in response to short-stimulus bursts, while components with nearly identical regions of activity in long-stimulus sessions from the same subjects were associated with single-peaked HRs. Thus, ICA combined with BOLD-image visualization can reveal dramatic and unforeseen HR variations not apparent to researchers analyzing their data with event-related response averaging and fixed HR templates.

[1]  P. O. White,et al.  A method for the rotation of higher-order factors. , 1966, The British journal of mathematical and statistical psychology.

[2]  J R Moeller,et al.  A Regional Covariance Approach to the Analysis of Functional Patterns in Positron Emission Tomographic Data , 1991, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[3]  R. Turner,et al.  Dynamic magnetic resonance imaging of human brain activity during primary sensory stimulation. , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[4]  Ravi S. Menon,et al.  Intrinsic signal changes accompanying sensory stimulation: functional brain mapping with magnetic resonance imaging. , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[5]  E C Wong,et al.  Processing strategies for time‐course data sets in functional mri of the human brain , 1993, Magnetic resonance in medicine.

[6]  S. Zeki A vision of the brain , 1993 .

[7]  A. Kleinschmidt,et al.  Brain or veinoxygenation or flow? On signal physiology in functional MRI of human brain activation , 1994, NMR in biomedicine.

[8]  Terrence J. Sejnowski,et al.  An Information-Maximization Approach to Blind Separation and Blind Deconvolution , 1995, Neural Computation.

[9]  Karl J. Friston,et al.  Commentary and Opinion: II. Statistical Parametric Mapping: Ontology and Current Issues , 1995, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[10]  Adrian T. Lee,et al.  Discrimination of Large Venous Vessels in Time‐Course Spiral Blood‐Oxygen‐Level‐Dependent Magnetic‐Resonance Functional Neuroimaging , 1995, Magnetic resonance in medicine.

[11]  Karl J. Friston,et al.  Spatial registration and normalization of images , 1995 .

[12]  T. L. Davis,et al.  Characterization of Cerebral Blood Oxygenation and Flow Changes during Prolonged Brain Activation , 2022 .

[13]  M. D’Esposito,et al.  A Trial-Based Experimental Design for fMRI , 1997, NeuroImage.

[14]  C. Genovese,et al.  Estimating test‐retest reliability in functional MR imaging I: Statistical methodology , 1997, Magnetic resonance in medicine.

[15]  Karl J. Friston,et al.  Event‐related f MRI , 1997, Human brain mapping.

[16]  Karl J. Friston Imaging cognitive anatomy , 1997, Trends in Cognitive Sciences.

[17]  M. D’Esposito,et al.  The variability of human BOLD hemodynamic responses , 1998, NeuroImage.

[18]  R. Turner,et al.  Event-Related fMRI: Characterizing Differential Responses , 1998, NeuroImage.

[19]  A. Dale,et al.  Functional–Anatomic Study of Episodic Retrieval II. Selective Averaging of Event-Related fMRI Trials to Test the Retrieval Success Hypothesis , 1998, NeuroImage.

[20]  Ravi S. Menon,et al.  Mental chronometry using latency-resolved functional MRI. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[21]  S Makeig,et al.  Spatially independent activity patterns in functional MRI data during the stroop color-naming task. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[22]  D. Schacter,et al.  Functional–Anatomic Study of Episodic Retrieval Using fMRI I. Retrieval Effort versus Retrieval Success , 1998, NeuroImage.

[23]  T. Sejnowski,et al.  Human Brain Mapping 6:368–372(1998) � Independent Component Analysis of fMRI Data: Examining the Assumptions , 2022 .

[24]  K Kawano,et al.  Sequential hemodynamic activation of motor areas and the draining veins during finger movements revealed by cross‐correlation between signals from fMRI , 1998, Neuroreport.

[25]  J. Rajapakse,et al.  Human Brain Mapping 6:283–300(1998) � Modeling Hemodynamic Response for Analysis of Functional MRI Time-Series , 2022 .

[26]  S Makeig,et al.  Analysis of fMRI data by blind separation into independent spatial components , 1998, Human brain mapping.

[27]  R. Buckner,et al.  Human Brain Mapping 6:373–377(1998) � Event-Related fMRI and the Hemodynamic Response , 2022 .

[28]  Mark A. Girolami,et al.  An Alternative Perspective on Adaptive Independent Component Analysis Algorithms , 1998, Neural Computation.

[29]  F Kruggel,et al.  Modeling the hemodynamic response in single‐trial functional MRI experiments , 1999, Magnetic resonance in medicine.

[30]  M. D’Esposito,et al.  The Effect of Normal Aging on the Coupling of Neural Activity to the Bold Hemodynamic Response , 1999, NeuroImage.

[31]  Terrence J. Sejnowski,et al.  Independent Component Analysis Using an Extended Infomax Algorithm for Mixed Sub-Gaussian and Super-Gaussian Sources , 1999, Neural Comput..

[32]  Terrence J. Sejnowski,et al.  Independent Component Analysis Using an Extended Infomax Algorithm for Mixed Subgaussian and Supergaussian Sources , 1999, Neural Computation.

[33]  Richard Bowtell,et al.  Detecting activations in event‐related fMRI using analysis of variance , 1999, Magnetic resonance in medicine.

[34]  T. Sejnowski,et al.  Functionally Independent Components of the Late Positive Event-Related Potential during Visual Spatial Attention , 1999, The Journal of Neuroscience.

[35]  A M Dale,et al.  Optimal experimental design for event‐related fMRI , 1999, Human brain mapping.

[36]  D. V. von Cramon,et al.  Temporal properties of the hemodynamic response in functional MRI , 1999, Human brain mapping.

[37]  V. Haughton,et al.  Whole-brain functional MR imaging activation from a finger-tapping task examined with independent component analysis. , 2000, AJNR. American journal of neuroradiology.

[38]  Karl J. Friston,et al.  A direct quantitative relationship between the functional properties of human and macaque V5 , 2000, Nature Neuroscience.

[39]  E. Gordon,et al.  The neural correlates of orienting: An integration of fMRI and skin conductance orienting , 2000, Neuroreport.

[40]  M. McKeown Detection of Consistently Task-Related Activations in fMRI Data with Hybrid Independent Component Analysis , 2000, NeuroImage.

[41]  M E Meyerand,et al.  Combining independent component analysis and correlation analysis to probe interregional connectivity in fMRI task activation datasets. , 2000, Magnetic resonance imaging.

[42]  J L Lancaster,et al.  Automated Talairach Atlas labels for functional brain mapping , 2000, Human brain mapping.

[43]  G. Orban,et al.  Attention Mechanisms in Visual SearchAn fMRI Study , 2000, Journal of Cognitive Neuroscience.

[44]  Mark Hallett,et al.  The variability of serial fMRI data: Correlation between a visual and a motor task , 2000, Neuroreport.

[45]  S.L. Gonzalez Andino,et al.  Measuring the complexity of time series: An application to neurophysiological signals , 2000, Human brain mapping.

[46]  S. Petersen,et al.  Characterizing the Hemodynamic Response: Effects of Presentation Rate, Sampling Procedure, and the Possibility of Ordering Brain Activity Based on Relative Timing , 2000, NeuroImage.

[47]  V D Calhoun,et al.  Spatial and temporal independent component analysis of functional MRI data containing a pair of task‐related waveforms , 2001, Human brain mapping.

[48]  D B Rowe,et al.  Bayesian source separation for reference function determination in fMRI , 2001, Magnetic resonance in medicine.

[49]  Scott A. Huettel,et al.  Dissociating the Neural Mechanisms of Visual Attention in Change Detection Using Functional MRI , 2001, Journal of Cognitive Neuroscience.

[50]  T. Sejnowski,et al.  Analysis and visualization of single‐trial event‐related potentials , 2001, Human brain mapping.

[51]  Tzyy-Ping Jung,et al.  Imaging brain dynamics using independent component analysis , 2001, Proc. IEEE.

[52]  D. Witoński,et al.  Dynamic magnetic resonance imaging. , 2002, Clinics in sports medicine.

[53]  R. Berguer Commentary and Opinion , 2004 .