A correction algorithm for partial volume effects in 3D PET imaging: principle and validation

Author

Reilhac, A. ; Rousset, O.G. ; Comtat, C. ; Frouin, V. ; Gregoire, M.C. ; Evans, A.C.

Author_Institution

McConnel Brain Imaging Centre, McGill Univ., Montreal, Que., Canada

Volume

3

fYear

2000

fDate

2000

Abstract

Presents a method for correcting 3D PET data for partial volume effects. The authors´ method assumes that the observed signal within a region of interest is a weighted sum of the true activities in the FOV of the scanner. The weighting coefficients represent the recovery and the cross-contamination factors between structures, and are estimated by 3D analytical simulation of a high resolution emitting model, such as a MRI segmented volume registered with the corresponding PET volume. The validation of the algorithm using well-controlled data sets, proved its efficiency to recover true time-activity curves in small structures, with errors smaller than 5%

Keywords

biomedical MRI; image segmentation; medical image processing; modelling; positron emission tomography; 3D PET imaging; 3D analytical simulation; MRI segmented volume; algorithm validation; correction algorithm; cross-contamination factors; high resolution emitting model; medical diagnostic imaging; nuclear medicine; partial volume effects; weighting coefficients; Analytical models; Brain; Contamination; Distortion measurement; Hospitals; Magnetic resonance imaging; Pollution measurement; Positron emission tomography; Signal resolution; Volume measurement;

fLanguage

English

Publisher

ieee

Conference_Titel

Nuclear Science Symposium Conference Record, 2000 IEEE

Conference_Location

Lyon

ISSN

1082-3654

Print_ISBN

0-7803-6503-8

Type

conf

DOI

10.1109/NSSMIC.2000.949232

Filename

949232