DocumentCode
3548531
Title
Volumetric partial volume quantification via a statistical model of 3-D voxel gradient magnitude
Author
Chiverton, J.P. ; Wells, K.
Author_Institution
Centre for Vision, Speech and Signal Process., Surrey Univ., Guildford
Volume
7
fYear
2004
fDate
16-22 Oct. 2004
Firstpage
4106
Lastpage
4110
Abstract
3-D volumetric data sets suffer from partial volume (PV) effects due to the finite bandwidth of the digital sampling process. A variety of approaches have been developed to quantify the PV effect in PET, SPECT, NMR and CT imaging modalities. Amongst these, voxel gradient magnitude information, modeled as a Rician distribution, has been suggested as a useful adjunct for statistical PV correction in 2-1) data. However, many biomedical image acquisition processes provide contiguous image slices arising from an acquisition process, which can be approximated to be 3-D in terms of the digital sampling process. Thus, classifiers using models that utilize extra information from the transverse or third perpendicular direction, in this case 3-D gradient magnitude information, should possess superior performance over algorithms that utilize lower dimensional information (e.g. intensity or 2D gradient features). Therefore, analytically derived probability distributions are presented to describe the 3-D gradient magnitude for 3-D isotropic and anisotropic data sets. A Bayesian classification framework, utilizing the 3-D isotropic and anisotropic gradient magnitude expressions, is compared with other models, illustrating superior performance for 3-D volumetric data
Keywords
biomedical MRI; medical image processing; positron emission tomography; single photon emission computed tomography; 2D gradient features; 3-D anisotropic data sets; 3-D isotropic data sets; 3-D volumetric data sets; 3-D voxel gradient magnitude; Bayesian classification framework; CT imaging modalities; NMR; PET; Rician distribution; SPECT; algorithms; biomedical image acquisition processes; contiguous image slices; digital sampling process; finite bandwidth; probability distributions; statistical PV correction; statistical model; volumetric partial volume quantification; Anisotropic magnetoresistance; Bandwidth; Bayesian methods; Biomedical imaging; Computed tomography; Image sampling; Nuclear magnetic resonance; Positron emission tomography; Probability distribution; Rician channels;
fLanguage
English
Publisher
ieee
Conference_Titel
Nuclear Science Symposium Conference Record, 2004 IEEE
Conference_Location
Rome
ISSN
1082-3654
Print_ISBN
0-7803-8700-7
Electronic_ISBN
1082-3654
Type
conf
DOI
10.1109/NSSMIC.2004.1466796
Filename
1466796
Link To Document