Model-based attenuation of movement artifacts in fMRI

Behavioral analysis of multi-joint arm reaching has allowed important advances in understanding the control of voluntary movements. Complementing this analysis with functional magnetic resonance imaging (fMRI) would give insight into the neural mechanisms behind this control. However, fMRI is very sensitive to artifacts created by head motion and magnetic field deformation caused by the moving limbs. It is thus necessary to attenuate these motion artifacts in order to obtain correct activation patterns. Most algorithms in literature were designed for slow changes of head position over several brain scans and are not very effective on data when the movement is of duration below the resolution of a brain scan. This paper introduces a simple model-based method to remove motion artifacts during short duration movements. The proposed algorithm can account for head movement and field deformations due to movements within and outside of the scanner's field of view. It uses information from the experimental design and subject kinematics to focus the artifact attenuation in time and space and minimize the loss of uncorrupted data. Applications of the algorithm on arm reaching experimental data obtained with blocked and event-related designs demonstrate attenuation of motion artifacts with minimal effect on the brain activations.

[1]  Rajesh Jugulum,et al.  Advantages and Limitations of MTS and MTGS , 2007 .

[2]  W. Orrison,et al.  Functional Brain Imaging , 1995 .

[3]  E. Bizzi,et al.  Human arm trajectory formation. , 1982, Brain : a journal of neurology.

[4]  Yasmin L. Hashambhoy,et al.  Neural Correlates of Reach Errors , 2005, The Journal of Neuroscience.

[5]  Etienne Burdet,et al.  A 2-DOF fMRI Compatible Haptic Interface to Interact with Arm Movements , 2006 .

[6]  E Burdet,et al.  A method for measuring endpoint stiffness during multi-joint arm movements. , 2000, Journal of biomechanics.

[7]  Raymond D. Kent The Speech Sciences , 1997 .

[8]  Robert Sessions Woodworth,et al.  THE ACCURACY OF VOLUNTARY MOVEMENT , 1899 .

[9]  Rieko Osu,et al.  CNS Learns Stable, Accurate, and Efficient Movements Using a Simple Algorithm , 2008, The Journal of Neuroscience.

[10]  O. Speck,et al.  Prospective Real-Time Slice-by-Slice Motion Correction for fMRI in Freely Moving Subjects , 2006, Magnetic Resonance Materials in Physics, Biology and Medicine.

[11]  J M Taveras,et al.  Magnetic Resonance in Medicine , 1991, The Western journal of medicine.

[12]  Raymond D. Kent The MIT Encyclopedia of Communication Disorders , 2003 .

[13]  F A Mussa-Ivaldi,et al.  Adaptive representation of dynamics during learning of a motor task , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[14]  Thomas H. Carr,et al.  Studying overt word reading and speech production with event-related fMRI: A method for detecting, assessing, and correcting articulation-induced signal changes and for measuring onset time and duration of articulation , 2008, Brain and Language.

[15]  Oliver Speck,et al.  Prospective Head Motion Compensation for MRI by Updating the Gradients and Radio Frequency During Data Acquisition , 2005, MICCAI.

[16]  Oliver Speck,et al.  Advantages and limitations of prospective head motion compensation for MRI using an optical motion tracking device. , 2006, Academic radiology.

[17]  Rieko Osu,et al.  The central nervous system stabilizes unstable dynamics by learning optimal impedance , 2001, Nature.

[18]  Scott T. Grafton,et al.  BOLD coherence reveals segregated functional neural interactions when adapting to distinct torque perturbations. , 2007, Journal of neurophysiology.

[19]  G. Barker,et al.  Study design in fMRI: Basic principles , 2006, Brain and Cognition.

[20]  E. Bizzi,et al.  Neural, mechanical, and geometric factors subserving arm posture in humans , 1985, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[21]  Karl J. Friston,et al.  Movement‐Related effects in fMRI time‐series , 1996, Magnetic resonance in medicine.

[22]  R. Turner,et al.  Characterization and Correction of Interpolation Effects in the Realignment of fMRI Time Series , 2000, NeuroImage.

[23]  Mitsuo Kawato,et al.  Equilibrium-Point Control Hypothesis Examined by Measured Arm Stiffness During Multijoint Movement , 1996, Science.

[24]  L. Freire,et al.  Motion Correction Algorithms May Create Spurious Brain Activations in the Absence of Subject Motion , 2001, NeuroImage.

[25]  Peter A. Bandettini,et al.  Experimental designs and processing strategies for fMRI studies involving overt verbal responses , 2004, NeuroImage.

[26]  G. Fullerton Psychology and physiology. , 1896 .

[27]  Jörn Diedrichsen,et al.  Detecting and adjusting for artifacts in fMRI time series data , 2005, NeuroImage.

[28]  Oliver Speck,et al.  Magnetic resonance imaging of freely moving objects: prospective real-time motion correction using an external optical motion tracking system , 2006, NeuroImage.

[29]  J. Flanagan,et al.  Neural Correlates of Internal-Model Loading , 2006, Current Biology.

[30]  Edward F. Jackson,et al.  Real‐time motion detection of functional MRI data , 2004, Journal of applied clinical medical physics.

[31]  C. Jack,et al.  Prospective multiaxial motion correction for fMRI , 2000, Magnetic resonance in medicine.

[32]  R. Gassert,et al.  MRI/fMRI-compatible robotic system with force feedback for interaction with human motion , 2006, IEEE/ASME Transactions on Mechatronics.

[33]  J. A. Pruszynski,et al.  Neural correlates , 2023 .

[34]  S Thesen,et al.  Prospective acquisition correction for head motion with image‐based tracking for real‐time fMRI , 2000, Magnetic resonance in medicine.

[35]  Remco J. Renken,et al.  Automated correction of spin-history related motion artefacts in fMRI: Simulated and phantom data , 2005, IEEE Transactions on Biomedical Engineering.

[36]  S J Riederer,et al.  A prospective approach to correct for inter‐image head rotation in FMRI , 1998, Magnetic resonance in medicine.

[37]  M. Hallett,et al.  Brain activity during visuomotor behavior triggered by arbitrary and spatially constrained cues: an fMRI study in humans , 2006, Experimental Brain Research.

[38]  C R Meyer,et al.  Motion correction in fMRI via registration of individual slices into an anatomical volume , 1999, Magnetic resonance in medicine.

[39]  R Gassert,et al.  Accurate real-time feedback of surface EMG during fMRI. , 2007, Journal of neurophysiology.