Adaptive reproducing kernel particle method for extraction of the cortical surface
We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is...
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| Published in | IEEE transactions on medical imaging Vol. 25; no. 6; pp. 755 - 767 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
IEEE
01.06.2006
The Institute of Electrical and Electronics Engineers, Inc. (IEEE) |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0278-0062 1558-254X |
| DOI | 10.1109/TMI.2006.873614 |
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| Abstract | We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. The proposed support generation method ensures that support of all particles cover the entire computational domains. The deformable model is adaptively adjusted by dilating the shape function and by inserting or merging particles in the high curvature regions or regions stopped by the target boundary. The shape function of the particle with a dilation parameter is adaptively constructed in response to particle insertion or merging. The proposed method offers flexibility in representing highly convolved structures and in refining the deformable models. Self-intersection of the surface, during evolution, is prevented by tracing backward along gradient descent direction from the crest interface of the distance field, which is computed by fast marching. These operations involve a significant computational cost. The initial model for the deformable surface is simple and requires no prior knowledge of the segmented structure. No specific template is required, e.g., an average cortical surface obtained from many subjects. The extracted cortical surface efficiently localizes the depths of the cerebral sulci, unlike some other active surface approaches that penalize regions of high curvature. Comparisons with manually segmented landmark data are provided to demonstrate the high accuracy of the proposed method. We also compare the proposed method to the finite element method, and to a commonly used cortical surface extraction approach, the CRUISE method. We also show that the independence of the shape functions of the RKPM from the underlying mesh enhances the convergence speed of the deformable model |
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| AbstractList | We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. The proposed support generation method ensures that support of all particles cover the entire computational domains. The deformable model is adaptively adjusted by dilating the shape function and by inserting or merging particles in the high curvature regions or regions stopped by the target boundary. The shape function of the particle with a dilation parameter is adaptively constructed in response to particle insertion or merging. The proposed method offers flexibility in representing highly convolved structures and in refining the deformable models. Self-intersection of the surface, during evolution, is prevented by tracing backward along gradient descent direction from the crest interface of the distance field, which is computed by fast marching. These operations involve a significant computational cost. The initial model for the deformable surface is simple and requires no prior knowledge of the segmented structure. No specific template is required, e.g., an average cortical surface obtained from many subjects. The extracted cortical surface efficiently localizes the depths of the cerebral sulci, unlike some other active surface approaches that penalize regions of high curvature. Comparisons with manually segmented landmark data are provided to demonstrate the high accuracy of the proposed method. We also compare the proposed method to the finite element method, and to a commonly used cortical surface extraction approach, the CRUISE method. We also show that the independence of the shape functions of the RKPM from the underlying mesh enhances the convergence speed of the deformable model. We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. The proposed support generation method ensures that support of all particles cover the entire computational domains. The deformable model is adaptively adjusted by dilating the shape function and by inserting or merging particles in the high curvature regions or regions stopped by the target boundary. The shape function of the particle with a dilation parameter is adaptively constructed in response to particle insertion or merging. The proposed method offers flexibility in representing highly convolved structures and in refining the deformable models. Self-intersection of the surface, during evolution, is prevented by tracing backward along gradient descent direction from the crest interface of the distance field, which is computed by fast marching. These operations involve a significant computational cost. The initial model for the deformable surface is simple and requires no prior knowledge of the segmented structure. No specific template is required, e.g., an average cortical surface obtained from many subjects. The extracted cortical surface efficiently localizes the depths of the cerebral sulci, unlike some other active surface approaches that penalize regions of high curvature. Comparisons with manually segmented landmark data are provided to demonstrate the high accuracy of the proposed method. We also compare the proposed method to the finite element method, and to a commonly used cortical surface extraction approach, the CRUISE method. We also show that the independence of the shape functions of the RKPM from the underlying mesh enhances the convergence speed of the deformable model We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. The proposed support generation method ensures that support of all particles cover the entire computational domains. The deformable model is adaptively adjusted by dilating the shape function and by inserting or merging particles in the high curvature regions or regions stopped by the target boundary. The shape function of the particle with a dilation parameter is adaptively constructed in response to particle insertion or merging. The proposed method offers flexibility in representing highly convolved structures and in refining the deformable models. Self-intersection of the surface, during evolution, is prevented by tracing backward along gradient descent direction from the crest interface of the distance field, which is computed by fast marching. These operations involve a significant computational cost. The initial model for the deformable surface is simple and requires no prior knowledge of the segmented structure. No specific template is required, e.g., an average cortical surface obtained from many subjects. The extracted cortical surface efficiently localizes the depths of the cerebral sulci, unlike some other active surface approaches that penalize regions of high curvature. Comparisons with manually segmented landmark data are provided to demonstrate the high accuracy of the proposed method. We also compare the proposed method to the finite element method, and to a commonly used cortical surface extraction approach, the CRUISE method. We also show that the independence of the shape functions of the RKPM from the underlying mesh enhances the convergence speed of the deformable m- - odel We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. The proposed support generation method ensures that support of all particles cover the entire computational domains. The deformable model is adaptively adjusted by dilating the shape function and by inserting or merging particles in the high curvature regions or regions stopped by the target boundary. The shape function of the particle with a dilation parameter is adaptively constructed in response to particle insertion or merging. The proposed method offers flexibility in representing highly convolved structures and in refining the deformable models. Self-intersection of the surface, during evolution, is prevented by tracing backward along gradient descent direction from the crest interface of the distance field, which is computed by fast marching. These operations involve a significant computational cost. The initial model for the deformable surface is simple and requires no prior knowledge of the segmented structure. No specific template is required, e.g., an average cortical surface obtained from many subjects. The extracted cortical surface efficiently localizes the depths of the cerebral sulci, unlike some other active surface approaches that penalize regions of high curvature. Comparisons with manually segmented landmark data are provided to demonstrate the high accuracy of the proposed method. We also compare the proposed method to the finite element method, and to a commonly used cortical surface extraction approach, the CRUISE method. We also show that the independence of the shape functions of the RKPM from the underlying mesh enhances the convergence speed of the deformable model.We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from three-dimensional (3-D) magnetic resonance images (MRIs). To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. The proposed support generation method ensures that support of all particles cover the entire computational domains. The deformable model is adaptively adjusted by dilating the shape function and by inserting or merging particles in the high curvature regions or regions stopped by the target boundary. The shape function of the particle with a dilation parameter is adaptively constructed in response to particle insertion or merging. The proposed method offers flexibility in representing highly convolved structures and in refining the deformable models. Self-intersection of the surface, during evolution, is prevented by tracing backward along gradient descent direction from the crest interface of the distance field, which is computed by fast marching. These operations involve a significant computational cost. The initial model for the deformable surface is simple and requires no prior knowledge of the segmented structure. No specific template is required, e.g., an average cortical surface obtained from many subjects. The extracted cortical surface efficiently localizes the depths of the cerebral sulci, unlike some other active surface approaches that penalize regions of high curvature. Comparisons with manually segmented landmark data are provided to demonstrate the high accuracy of the proposed method. We also compare the proposed method to the finite element method, and to a commonly used cortical surface extraction approach, the CRUISE method. We also show that the independence of the shape functions of the RKPM from the underlying mesh enhances the convergence speed of the deformable model. To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of the equilibrium equations. |
| Author | Toga, A.W. Thompson, P.M. Meihe Xu |
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| References_xml | – volume: 2167 start-page: 327 year: 1994 ident: ref24 article-title: finite element approach to warping of brain images publication-title: Proc SPIE Medical Imaging Image Processing – ident: ref1 doi: 10.1007/BF00133570 – volume: 5 start-page: 425 year: 1997 ident: ref46 article-title: brainweb: online interface to a 3d mri simulated brain database publication-title: NeuroImage – ident: ref10 doi: 10.1016/S1361-8415(96)80008-9 – ident: ref17 doi: 10.1016/j.neuroimage.2004.06.043 – ident: ref23 doi: 10.1109/34.244675 – ident: ref3 doi: 10.1073/pnas.90.24.11944 – year: 1977 ident: ref29 publication-title: The Finite Element Method (3rd edition) – ident: ref44 doi: 10.1073/pnas.93.18.9389 – start-page: 140 year: 1999 ident: ref11 article-title: an adaptive fuzzy segmentation algorithm for three dimensional magnetic resonance images publication-title: Proc 16th Int Conf Information Processing in Medical Imaging (IPMI'99) doi: 10.1007/3-540-48714-X_11 – ident: ref6 doi: 10.1109/42.811276 – year: 1991 ident: ref2 publication-title: HANDS A Pattern-Theoretic Study Of Biological Shapes – ident: ref26 doi: 10.1109/34.85659 – ident: ref8 doi: 10.1109/42.552054 – ident: ref37 doi: 10.1073/pnas.95.15.8431 – ident: ref45 doi: 10.1007/s004660050170 – ident: ref13 doi: 10.1109/42.781013 – ident: ref22 doi: 10.1016/0004-3702(88)90080-X – ident: ref15 doi: 10.1006/nimg.1999.0534 – ident: ref47 doi: 10.1145/37402.37422 – ident: ref12 doi: 10.1006/nimg.1999.0428 – ident: ref42 doi: 10.1006/cgip.1994.1019 – ident: ref9 doi: 10.1006/nimg.1998.0395 – ident: ref32 doi: 10.1016/0010-4655(88)90026-4 – ident: ref14 doi: 10.1109/42.544496 – year: 2004 ident: ref36 publication-title: Meshless Geometric Subdivision – ident: ref4 doi: 10.1109/CVPR.1993.341080 – ident: ref39 doi: 10.1016/0045-7949(72)90020-X – ident: ref38 doi: 10.1006/cviu.2000.0875 – ident: ref16 doi: 10.1007/978-3-540-39701-4_5 – ident: ref19 doi: 10.1016/S1361-8415(02)00054-3 – ident: ref27 doi: 10.1016/S1361-8415(01)00045-7 – ident: ref31 doi: 10.1002/(SICI)1097-0207(19970430)40:8<1449::AID-NME121>3.0.CO;2-Z – ident: ref33 doi: 10.1007/BF00364252 – ident: ref35 doi: 10.1002/(SICI)1098-2426(199611)12:6<673::AID-NUM3>3.0.CO;2-P – ident: ref7 doi: 10.1162/jocn.1993.5.2.162 – ident: ref21 doi: 10.1016/1049-9660(92)90003-L – ident: ref34 doi: 10.1088/0965-0393/2/3A/007 – ident: ref18 doi: 10.1109/TPAMI.2003.1201824 – ident: ref20 doi: 10.1109/34.57681 – ident: ref28 doi: 10.1109/42.974933 – ident: ref41 doi: 10.1109/83.661186 – ident: ref40 doi: 10.1016/0045-7949(75)90018-8 – ident: ref30 doi: 10.1002/fld.1650200824 – ident: ref43 doi: 10.1016/S0045-7825(96)01086-9 – ident: ref5 doi: 10.1006/jcph.1995.1098 – ident: ref25 doi: 10.1016/0895-6111(94)00040-9 |
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| Snippet | We propose a novel adaptive approach based on the Reproducing Kernel Particle Method (RKPM) to extract the cortical surfaces of the brain from... To formulate the discrete equations of the deformable model, a flexible particle shape function is employed in the Galerkin approximation of the weak form of... |
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| SubjectTerms | Adaptive refinement Algorithms Artificial Intelligence Atoms & subatomic particles Cerebral Cortex - anatomy & histology Computational efficiency Computer interfaces cortex extraction Data mining Deformable models Equations Finite element analysis Humans Image Enhancement - methods Image Interpretation, Computer-Assisted - methods Imaging, Three-Dimensional - methods Information Storage and Retrieval - methods Kernel Magnetic resonance Magnetic resonance imaging Magnetic Resonance Imaging - methods Merging MRI Pattern Recognition, Automated - methods Reproducibility of Results reproducing kernel particle Sensitivity and Specificity Shape Studies |
| Title | Adaptive reproducing kernel particle method for extraction of the cortical surface |
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