Lesion quantification in oncological positron emission tomography: A maximum likelihood partial volume correction strategy

Lesion quantification in oncological positron emission tomography: A maximum likelihood partial volume correction strategy

A maximum likelihood (ML) partial volume effect correction (PVEC) strategy for the quantification of uptake and volume of oncological lesions in F 18 -FDG positron emission tomography is proposed. The algorithm is based on the application of ML reconstruction on volumetric regional basis functions i...

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Bibliographic Details
Published in:Medical physics (Lancaster) Vol. 36; no. 7; pp. 3040 - 3049
Main Authors: De Bernardi, Elisabetta, Faggiano, Elena, Zito, Felicia, Gerundini, Paolo, Baselli, Giuseppe
Format: Journal Article
Language:English
Published: United States American Association of Physicists in Medicine 01-07-2009
Subjects:
Algorithms
Cancer
Fluorodeoxyglucose F18
Image Interpretation, Computer-Assisted - methods
image reconstruction
image resolution
Image scanners
image segmentation
Iteration theory
iterative methods
Likelihood Functions
maximum likelihood estimation
maximum likelihood reconstruction
Medical image artifacts
Medical image noise
medical image processing
Medical image reconstruction
Medical image smoothing
Medical imaging
Neoplasms - diagnostic imaging
Numerical approximation and analysis
partial volume effect correction
PET
phantoms
Phantoms, Imaging
positron emission tomography
Positron emission tomography (PET)
Positron-Emission Tomography - methods
Positron-Emission Tomography - statistics & numerical data
Probability theory, stochastic processes, and statistics
Radiography
Reconstruction
regional basis functions
Segmentation
tumours
uptake quantification
volume estimate
wounds
partial volume effect correction
volume estimate
maximum likelihood reconstruction
uptake quantification
PET
regional basis functions
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Summary:A maximum likelihood (ML) partial volume effect correction (PVEC) strategy for the quantification of uptake and volume of oncological lesions in F 18 -FDG positron emission tomography is proposed. The algorithm is based on the application of ML reconstruction on volumetric regional basis functions initially defined on a smooth standard clinical image and iteratively updated in terms of their activity and volume. The volume of interest (VOI) containing a previously detected region is segmented by a k -means algorithm in three regions: A central region surrounded by a partial volume region and a spill-out region. All volume outside the VOI (background with all other structures) is handled as a unique basis function and therefore “frozen” in the reconstruction process except for a gain coefficient. The coefficients of the regional basis functions are iteratively estimated with an attenuation-weighted ordered subset expectation maximization (AWOSEM) algorithm in which a 3D, anisotropic, space variant model of point spread function (PSF) is included for resolution recovery. The reconstruction-segmentation process is iterated until convergence; at each iteration, segmentation is performed on the reconstructed image blurred by the system PSF in order to update the partial volume and spill-out regions. The developed PVEC strategy was tested on sphere phantom studies with activity contrasts of 7.5 and 4 and compared to a conventional recovery coefficient method. Improved volume and activity estimates were obtained with low computational costs, thanks to blur recovery and to a better local approximation to ML convergence.
Bibliography:elisabetta.debernardi@polimi.it
Author to whom correspondence should be addressed. Electronic mail
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ISSN:0094-2405
2473-4209
DOI:10.1118/1.3130019