Guy Marchal scite author profile

Abstract-A new approach to the problem of multimodality medical image registration is proposed, using a basic concept from information theory, Mutual Information or relative entropy, as a new matching criterion. The method presented in this paper applies Mutual Information to measure the statistical dependence or information redundancy between the image intensities of corresponding voxels in both images, which is assumed to be maximal if the images are geometrically aligned. Maximization of Mutual Information is a very general and powerful criterion, because no assumptions are made regarding the nature of this dependence and no limiting constraints are imposed on the image content of the modalities involved. The accuracy of the mutual information criterion is validated for rigid body registration of CT, MR and PET images by comparison with the stereotactic registration solution, while robustness is evaluated with respect to implementation issues, such as interpolation and optimization, and image content, including partial overlap and image degradation. Our results demonstrate that subvoxel accuracy with respect to the stereotactic reference solution can be achieved completely automatically and without any prior segmentation, feature extraction or other pre-processing steps, which makes this method very well suited for clinical applications.

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An iterative maximum-likelihood polychromatic algorithm for CT

Man¹,

Nuyts²,

Dupont³

et al. 2001

IEEE Trans. Med. Imaging

384

308

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Comparison between effective radiation dose of CBCT and MSCT scanners for dentomaxillofacial applications

Loubele

Bogaerts

Dijck

et al. 2009

European Journal of Radiology

443

280

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Motion-responsive regions of the human brain

et al. 1999

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Functional magnetic resonance imaging was used to map motion responsive regions of the human brain by contrasting passive viewing of moving and stationary randomly textured patterns. Regions were retained as motion responsive if they reached significance either in the group analysis or in the majority of hemispheres in single-subject analysis. They include well-known regions, such as V1, hMT/V5+, and hV3A, but also several occipito-temporal, occipito-parietal, parietal, and frontal regions. The time course of the activation was similar in most of these regions. Motion responses were nearly identical for binocular and monocular presentations. Flicker-induced-activation introduced a dichotomy amongst these motion responsive regions. Early occipital and occipito-temporal regions responded well to flicker, while flicker responses gradually vanished as one moved to occipito-parietal and then parietal regions. Finally, over a more than four-fold range, stimulus diameter had little effect on the motion activations, except in V1.

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Local Recurrence After Hepatic Radiofrequency Coagulation

Mulier

Ni²,

Jamart³

et al. 2005

621

174

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Metal streak artifacts in X-ray computed tomography: a simulation study

Man

Nuyts

Dupont

et al. 1999

IEEE Trans. Nucl. Sci.

249

159

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Ovarian Vein Embolization for the Treatment of Pelvic Congestion Syndrome: Long-Term Technical and Clinical Results

Maleux

Stockx

Wilms

et al. 2000

Journal of Vascular and Interventional Radiology

185

137

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Human Cortical Regions Involved in Extracting Depth from Motion

Orban

Sunaert

Todd

et al. 1999

Neuron

166

130

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We used functional magnetic resonance imaging (fMRI) to investigate brain regions involved in extracting three-dimensional structure from motion. A factorial design included two-dimensional and three-dimensional structures undergoing rigid and nonrigid motions. As predicted from monkey data, the human homolog of MT/V5 was significantly more active when subjects viewed three-dimensional (as opposed to two-dimensional) displays, irrespective of their rigidity. Human MT/V5+ (hMT/V5+) is part of a network with right hemisphere dominance involved in extracting depth from motion, including a lateral occipital region, five sites along the intraparietal sulcus (IPS), and two ventral occipital regions. Control experiments confirmed that this pattern of activation is most strongly correlated with perceived three-dimensional structure, in as much as it arises from motion and cannot be attributed to numerous two-dimensional image properties or to saliency.

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Guy Marchal

Multimodality image registration by maximization of mutual information

An iterative maximum-likelihood polychromatic algorithm for CT

Comparison between effective radiation dose of CBCT and MSCT scanners for dentomaxillofacial applications

Motion-responsive regions of the human brain

Local Recurrence After Hepatic Radiofrequency Coagulation

Metal streak artifacts in X-ray computed tomography: a simulation study

Ovarian Vein Embolization for the Treatment of Pelvic Congestion Syndrome: Long-Term Technical and Clinical Results

Human Cortical Regions Involved in Extracting Depth from Motion

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