3D dense local point descriptors for mouse brain gene expression images

Yen H. Le; Uday Kurkure; Ioannis A. Kakadiaris

doi:10.1016/j.compmedimag.2014.03.006

3D dense local point descriptors for mouse brain gene expression images

Yen H. Le, Uday Kurkure, Ioannis A. Kakadiaris

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Anatomical landmarks play an important role in many biomedical image analysis applications (e.g., registration and segmentation). Landmark detection can be computationally very expensive, especially in 3D images, because every single voxel in a region of interest may need to be evaluated. In this paper, we introduce two 3D local image descriptors which can be computed simultaneously for every voxel in a volume. Both our proposed descriptors are extensions of the DAISY descriptor, a popular descriptor that is based on the histograms of oriented gradients and was named after its daisy-flower-like configuration. Our experiments on mouse brain gene expression images indicate that our descriptors are discriminative and are able to reduce the detection errors of landmark points more than 30% when compared with SIFT-3D, an extension in 3D of SIFT (scale-invariant feature transform). We also demonstrate that our descriptors are more computationally efficient than SIFT-3D and n-SIFT (an extension SIFT in n-dimensions) for densely sampled points. Therefore, our descriptors can be used in applications that require computation of the descriptors at densely sampled points (e.g., landmark point detection or feature-based registration).

Original language	English (US)
Pages (from-to)	326-336
Number of pages	11
Journal	Computerized Medical Imaging and Graphics
Volume	38
Issue number	5
DOIs	https://doi.org/10.1016/j.compmedimag.2014.03.006
State	Published - Jul 2014

Keywords

3D descriptor
Biomedical image processing
DAISY
Feature extraction
Landmark points
SIFT

ASJC Scopus subject areas

Radiological and Ultrasound Technology
Radiology Nuclear Medicine and imaging
Computer Vision and Pattern Recognition
Health Informatics
Computer Graphics and Computer-Aided Design

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10.1016/j.compmedimag.2014.03.006

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@article{cfabfe32d68b446d8f50fb12211c9200,

title = "3D dense local point descriptors for mouse brain gene expression images",

abstract = "Anatomical landmarks play an important role in many biomedical image analysis applications (e.g., registration and segmentation). Landmark detection can be computationally very expensive, especially in 3D images, because every single voxel in a region of interest may need to be evaluated. In this paper, we introduce two 3D local image descriptors which can be computed simultaneously for every voxel in a volume. Both our proposed descriptors are extensions of the DAISY descriptor, a popular descriptor that is based on the histograms of oriented gradients and was named after its daisy-flower-like configuration. Our experiments on mouse brain gene expression images indicate that our descriptors are discriminative and are able to reduce the detection errors of landmark points more than 30% when compared with SIFT-3D, an extension in 3D of SIFT (scale-invariant feature transform). We also demonstrate that our descriptors are more computationally efficient than SIFT-3D and n-SIFT (an extension SIFT in n-dimensions) for densely sampled points. Therefore, our descriptors can be used in applications that require computation of the descriptors at densely sampled points (e.g., landmark point detection or feature-based registration).",

keywords = "3D descriptor, Biomedical image processing, DAISY, Feature extraction, Landmark points, SIFT",

author = "Le, {Yen H.} and Uday Kurkure and Kakadiaris, {Ioannis A.}",

note = "Funding Information: Ioannis Kakadiaris is a Hugh and Lillie Cranz Cullen Distinguished University Professor of Computer Science, Electrical and Computer Engineering, and Biomedical Engineering at the University of Houston, Houston, TX, USA. He received the Ptychion (BSc) degree in physics from the University of Athens, Greece, in 1989, the M.Sc. degree in computer science from Northeastern University, Boston, Massachusetts, in 1991, and the Ph.D. degree in computer science from the University of Pennsylvania, Philadelphia, in 1997. Dr. Kakadiaris joined the University of Houston (UH) in August 1997 after completing a postdoctoral fellowship at the University of Pennsylvania. He is the founder and director of UH's Computational Biomedicine Laboratory (formerly the Visual Computing Lab) and director of the Division of Bio-Imaging and Bio-Computation at the UH Institute for Digital Informatics and Analysis. Professor Kakadiaris{\textquoteright} research interests include biomedical image analysis, biometrics, computer vision, and pattern recognition. He is the recipient of an NSF Early Career Development Award (2000), UH Computer Science Research Excellence Award, UH Enron Teaching Excellence Award, James Muller VP Young Investigator Prize, and the Schlumberger Technical Foundation Award.",

year = "2014",

month = jul,

doi = "10.1016/j.compmedimag.2014.03.006",

language = "English (US)",

volume = "38",

pages = "326--336",

journal = "Computerized Medical Imaging and Graphics",

issn = "0895-6111",

publisher = "Elsevier Limited",

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T1 - 3D dense local point descriptors for mouse brain gene expression images

AU - Le, Yen H.

AU - Kurkure, Uday

AU - Kakadiaris, Ioannis A.

N1 - Funding Information: Ioannis Kakadiaris is a Hugh and Lillie Cranz Cullen Distinguished University Professor of Computer Science, Electrical and Computer Engineering, and Biomedical Engineering at the University of Houston, Houston, TX, USA. He received the Ptychion (BSc) degree in physics from the University of Athens, Greece, in 1989, the M.Sc. degree in computer science from Northeastern University, Boston, Massachusetts, in 1991, and the Ph.D. degree in computer science from the University of Pennsylvania, Philadelphia, in 1997. Dr. Kakadiaris joined the University of Houston (UH) in August 1997 after completing a postdoctoral fellowship at the University of Pennsylvania. He is the founder and director of UH's Computational Biomedicine Laboratory (formerly the Visual Computing Lab) and director of the Division of Bio-Imaging and Bio-Computation at the UH Institute for Digital Informatics and Analysis. Professor Kakadiaris’ research interests include biomedical image analysis, biometrics, computer vision, and pattern recognition. He is the recipient of an NSF Early Career Development Award (2000), UH Computer Science Research Excellence Award, UH Enron Teaching Excellence Award, James Muller VP Young Investigator Prize, and the Schlumberger Technical Foundation Award.

PY - 2014/7

Y1 - 2014/7

N2 - Anatomical landmarks play an important role in many biomedical image analysis applications (e.g., registration and segmentation). Landmark detection can be computationally very expensive, especially in 3D images, because every single voxel in a region of interest may need to be evaluated. In this paper, we introduce two 3D local image descriptors which can be computed simultaneously for every voxel in a volume. Both our proposed descriptors are extensions of the DAISY descriptor, a popular descriptor that is based on the histograms of oriented gradients and was named after its daisy-flower-like configuration. Our experiments on mouse brain gene expression images indicate that our descriptors are discriminative and are able to reduce the detection errors of landmark points more than 30% when compared with SIFT-3D, an extension in 3D of SIFT (scale-invariant feature transform). We also demonstrate that our descriptors are more computationally efficient than SIFT-3D and n-SIFT (an extension SIFT in n-dimensions) for densely sampled points. Therefore, our descriptors can be used in applications that require computation of the descriptors at densely sampled points (e.g., landmark point detection or feature-based registration).

AB - Anatomical landmarks play an important role in many biomedical image analysis applications (e.g., registration and segmentation). Landmark detection can be computationally very expensive, especially in 3D images, because every single voxel in a region of interest may need to be evaluated. In this paper, we introduce two 3D local image descriptors which can be computed simultaneously for every voxel in a volume. Both our proposed descriptors are extensions of the DAISY descriptor, a popular descriptor that is based on the histograms of oriented gradients and was named after its daisy-flower-like configuration. Our experiments on mouse brain gene expression images indicate that our descriptors are discriminative and are able to reduce the detection errors of landmark points more than 30% when compared with SIFT-3D, an extension in 3D of SIFT (scale-invariant feature transform). We also demonstrate that our descriptors are more computationally efficient than SIFT-3D and n-SIFT (an extension SIFT in n-dimensions) for densely sampled points. Therefore, our descriptors can be used in applications that require computation of the descriptors at densely sampled points (e.g., landmark point detection or feature-based registration).

KW - 3D descriptor

KW - Biomedical image processing

KW - DAISY

KW - Feature extraction

KW - Landmark points

KW - SIFT

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JO - Computerized Medical Imaging and Graphics

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ER -

3D dense local point descriptors for mouse brain gene expression images

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Keywords

ASJC Scopus subject areas

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