3D active shape models of human brain structures: Application to patient-specific mesh generation

Nishant Ravikumar; Isaac Castro-Mateos; Jose M. Pozo; Alejandro F. Frangi; Zeike A. Taylor

doi:10.1117/12.2082599

3D active shape models of human brain structures: Application to patient-specific mesh generation

Nishant Ravikumar^*, Isaac Castro-Mateos, Jose M. Pozo, Alejandro F. Frangi, Zeike A. Taylor

^*Corresponding author for this work

The University of Sheffield

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

The use of biomechanics-based numerical simulations has attracted growing interest in recent years for computer-aided diagnosis and treatment planning. With this in mind, a method for automatic mesh generation of brain structures of interest, using statistical models of shape (SSM) and appearance (SAM), for personalised computational modelling is presented. SSMs are constructed as point distribution models (PDMs) while SAMs are trained using intensity profiles sampled from a training set of T1-weighted magnetic resonance images. The brain structures of interest are, the cortical surface (cerebrum, cerebellum & brainstem), lateral ventricles and falx-cerebri membrane. Two methods for establishing correspondences across the training set of shapes are investigated and compared (based on SSM quality): the Coherent Point Drift (CPD) point-set registration method and B-spline mesh-to-mesh registration method. The MNI-305 (Montreal Neurological Institute) average brain atlas is used to generate the template mesh, which is deformed and registered to each training case, to establish correspondence over the training set of shapes. 18 healthy patients T1-weightedMRimages form the training set used to generate the SSM and SAM. Both model-training and model-fitting are performed over multiple brain structures simultaneously. Compactness and generalisation errors of the BSpline-SSM and CPD-SSM are evaluated and used to quantitatively compare the SSMs. Leave-one-out cross validation is used to evaluate SSM quality in terms of these measures. The mesh-based SSM is found to generalise better and is more compact, relative to the CPD-based SSM. Quality of the best-fit model instance from the trained SSMs, to test cases are evaluated using the Hausdorff distance (HD) and mean absolute surface distance (MASD) metrics.

Original language	English
Title of host publication	Medical Imaging 2015
Subtitle of host publication	Computer-Aided Diagnosis
Editors	Lubomir M. Hadjiiski, Georgia D. Tourassi
Publisher	SPIE
ISBN (Electronic)	9781628415049
ISBN (Print)	9781628415049
DOIs	https://doi.org/10.1117/12.2082599
Publication status	Published - 2015
Event	SPIE Medical Imaging Symposium 2015: Computer-Aided Diagnosis - Orlando, United States Duration: 22 Feb 2015 → 25 Feb 2015

Publication series

Name	Progress in Biomedical Optics and Imaging - Proceedings of SPIE
Volume	9414
ISSN (Print)	1605-7422

Conference

Conference	SPIE Medical Imaging Symposium 2015: Computer-Aided Diagnosis
Country/Territory	United States
City	Orlando
Period	22/02/15 → 25/02/15

Keywords

BSpline registration
Coherent point drift (CPD) registration
Cortical surface
Falx-cerebri membrane
Lateral ventricles
Principal component analysis (PCA)
Statistical appearance models (SAMs)
Statistical shape models (SSMs)

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10.1117/12.2082599

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Ravikumar, N., Castro-Mateos, I., Pozo, J. M., Frangi, A. F., & Taylor, Z. A. (2015). 3D active shape models of human brain structures: Application to patient-specific mesh generation. In L. M. Hadjiiski, & G. D. Tourassi (Eds.), Medical Imaging 2015: Computer-Aided Diagnosis Article 94142D (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 9414). SPIE. https://doi.org/10.1117/12.2082599

@inproceedings{54e15101f1ad4fd087ab59005216683b,

title = "3D active shape models of human brain structures: Application to patient-specific mesh generation",

abstract = "The use of biomechanics-based numerical simulations has attracted growing interest in recent years for computer-aided diagnosis and treatment planning. With this in mind, a method for automatic mesh generation of brain structures of interest, using statistical models of shape (SSM) and appearance (SAM), for personalised computational modelling is presented. SSMs are constructed as point distribution models (PDMs) while SAMs are trained using intensity profiles sampled from a training set of T1-weighted magnetic resonance images. The brain structures of interest are, the cortical surface (cerebrum, cerebellum & brainstem), lateral ventricles and falx-cerebri membrane. Two methods for establishing correspondences across the training set of shapes are investigated and compared (based on SSM quality): the Coherent Point Drift (CPD) point-set registration method and B-spline mesh-to-mesh registration method. The MNI-305 (Montreal Neurological Institute) average brain atlas is used to generate the template mesh, which is deformed and registered to each training case, to establish correspondence over the training set of shapes. 18 healthy patients T1-weightedMRimages form the training set used to generate the SSM and SAM. Both model-training and model-fitting are performed over multiple brain structures simultaneously. Compactness and generalisation errors of the BSpline-SSM and CPD-SSM are evaluated and used to quantitatively compare the SSMs. Leave-one-out cross validation is used to evaluate SSM quality in terms of these measures. The mesh-based SSM is found to generalise better and is more compact, relative to the CPD-based SSM. Quality of the best-fit model instance from the trained SSMs, to test cases are evaluated using the Hausdorff distance (HD) and mean absolute surface distance (MASD) metrics.",

keywords = "BSpline registration, Coherent point drift (CPD) registration, Cortical surface, Falx-cerebri membrane, Lateral ventricles, Principal component analysis (PCA), Statistical appearance models (SAMs), Statistical shape models (SSMs)",

author = "Nishant Ravikumar and Isaac Castro-Mateos and Pozo, {Jose M.} and Frangi, {Alejandro F.} and Taylor, {Zeike A.}",

note = "Publisher Copyright: {\textcopyright} 2015 SPIE.; SPIE Medical Imaging Symposium 2015: Computer-Aided Diagnosis ; Conference date: 22-02-2015 Through 25-02-2015",

year = "2015",

doi = "10.1117/12.2082599",

language = "English",

isbn = "9781628415049",

series = "Progress in Biomedical Optics and Imaging - Proceedings of SPIE",

publisher = "SPIE",

editor = "Hadjiiski, {Lubomir M.} and Tourassi, {Georgia D.}",

booktitle = "Medical Imaging 2015",

address = "United States",

}

Ravikumar, N, Castro-Mateos, I, Pozo, JM, Frangi, AF & Taylor, ZA 2015, 3D active shape models of human brain structures: Application to patient-specific mesh generation. in LM Hadjiiski & GD Tourassi (eds), Medical Imaging 2015: Computer-Aided Diagnosis., 94142D, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, vol. 9414, SPIE, SPIE Medical Imaging Symposium 2015: Computer-Aided Diagnosis, Orlando, United States, 22/02/15. https://doi.org/10.1117/12.2082599

3D active shape models of human brain structures: Application to patient-specific mesh generation. / Ravikumar, Nishant; Castro-Mateos, Isaac; Pozo, Jose M. et al.
Medical Imaging 2015: Computer-Aided Diagnosis. ed. / Lubomir M. Hadjiiski; Georgia D. Tourassi. SPIE, 2015. 94142D (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 9414).

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - 3D active shape models of human brain structures

T2 - SPIE Medical Imaging Symposium 2015: Computer-Aided Diagnosis

AU - Ravikumar, Nishant

AU - Castro-Mateos, Isaac

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AU - Frangi, Alejandro F.

AU - Taylor, Zeike A.

PY - 2015

Y1 - 2015

N2 - The use of biomechanics-based numerical simulations has attracted growing interest in recent years for computer-aided diagnosis and treatment planning. With this in mind, a method for automatic mesh generation of brain structures of interest, using statistical models of shape (SSM) and appearance (SAM), for personalised computational modelling is presented. SSMs are constructed as point distribution models (PDMs) while SAMs are trained using intensity profiles sampled from a training set of T1-weighted magnetic resonance images. The brain structures of interest are, the cortical surface (cerebrum, cerebellum & brainstem), lateral ventricles and falx-cerebri membrane. Two methods for establishing correspondences across the training set of shapes are investigated and compared (based on SSM quality): the Coherent Point Drift (CPD) point-set registration method and B-spline mesh-to-mesh registration method. The MNI-305 (Montreal Neurological Institute) average brain atlas is used to generate the template mesh, which is deformed and registered to each training case, to establish correspondence over the training set of shapes. 18 healthy patients T1-weightedMRimages form the training set used to generate the SSM and SAM. Both model-training and model-fitting are performed over multiple brain structures simultaneously. Compactness and generalisation errors of the BSpline-SSM and CPD-SSM are evaluated and used to quantitatively compare the SSMs. Leave-one-out cross validation is used to evaluate SSM quality in terms of these measures. The mesh-based SSM is found to generalise better and is more compact, relative to the CPD-based SSM. Quality of the best-fit model instance from the trained SSMs, to test cases are evaluated using the Hausdorff distance (HD) and mean absolute surface distance (MASD) metrics.

AB - The use of biomechanics-based numerical simulations has attracted growing interest in recent years for computer-aided diagnosis and treatment planning. With this in mind, a method for automatic mesh generation of brain structures of interest, using statistical models of shape (SSM) and appearance (SAM), for personalised computational modelling is presented. SSMs are constructed as point distribution models (PDMs) while SAMs are trained using intensity profiles sampled from a training set of T1-weighted magnetic resonance images. The brain structures of interest are, the cortical surface (cerebrum, cerebellum & brainstem), lateral ventricles and falx-cerebri membrane. Two methods for establishing correspondences across the training set of shapes are investigated and compared (based on SSM quality): the Coherent Point Drift (CPD) point-set registration method and B-spline mesh-to-mesh registration method. The MNI-305 (Montreal Neurological Institute) average brain atlas is used to generate the template mesh, which is deformed and registered to each training case, to establish correspondence over the training set of shapes. 18 healthy patients T1-weightedMRimages form the training set used to generate the SSM and SAM. Both model-training and model-fitting are performed over multiple brain structures simultaneously. Compactness and generalisation errors of the BSpline-SSM and CPD-SSM are evaluated and used to quantitatively compare the SSMs. Leave-one-out cross validation is used to evaluate SSM quality in terms of these measures. The mesh-based SSM is found to generalise better and is more compact, relative to the CPD-based SSM. Quality of the best-fit model instance from the trained SSMs, to test cases are evaluated using the Hausdorff distance (HD) and mean absolute surface distance (MASD) metrics.

KW - BSpline registration

KW - Coherent point drift (CPD) registration

KW - Cortical surface

KW - Falx-cerebri membrane

KW - Lateral ventricles

KW - Principal component analysis (PCA)

KW - Statistical appearance models (SAMs)

KW - Statistical shape models (SSMs)

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DO - 10.1117/12.2082599

M3 - Conference contribution

AN - SCOPUS:84948783554

SN - 9781628415049

T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE

BT - Medical Imaging 2015

A2 - Hadjiiski, Lubomir M.

A2 - Tourassi, Georgia D.

PB - SPIE

Y2 - 22 February 2015 through 25 February 2015

ER -

3D active shape models of human brain structures: Application to patient-specific mesh generation

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Publication series

Conference

Keywords

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