DocumentCode
2052976
Title
Influence of collimator hole dimensions on parallel and cone-beam brain SPECT
Author
Kamphuis, C. ; Beekman, F.J. ; Hutton, B.F.
Author_Institution
Image Sci. Inst., Utrecht Univ. Hospital, Netherlands
Volume
2
fYear
1999
fDate
1999
Firstpage
1047
Abstract
This study assesses the influence of collimator hole dimensions on the accuracy of brain SPECT. To this end, four low energy, parallel hole (PH) collimators and four low energy, half cone beam (CB) collimators with different hole dimensions were simulated. The simulated projection data were representative of Ultra High Resolution (UHR), High Resolution (HR), Medium Resolution (MR), and General Purpose (GP) collimators. Reconstruction was performed with the Ordered Subsets Expectation Maximization (OS-FM) algorithm with and without correction for the camera response (CRC and NCRC, respectively). The distance-dependent blurring kernel used in CRC matched the blurring used in the simulations. Image accuracy was assessed by calculating contrast-to-noise ratios (CTN) in a phantom containing cold spheres and by calculating Mean Squared Errors (MSE) between the true 3D Hoffman brain phantom and its reconstructions. For the accuracy of PH collimators, results indicate that when NCRC is applied, the UHR collimator results in better CTN ratios and lower MSE than the collimators with lower resolution. However, when CRC is applied, the GP collimator outperforms the higher resolution collimators. For the CB collimators, the low resolution collimators (GP and MR) result in the best CTN ratios and the lowest MSE, regardless if CRC is applied
Keywords
brain; image reconstruction; image resolution; medical image processing; single photon emission computed tomography; camera response correction; collimator hole dimensions; cone-beam brain SPECT; distance-dependent blurring kernel; image accuracy; mean squared errors; medical diagnostic imaging; nuclear medicine; ordered subsets expectation maximization algorithm; parallel brain SPECT; phantom containing cold spheres; true 3D Hoffman brain phantom; Brain modeling; Cameras; Collimators; Cyclic redundancy check; Energy resolution; Hospitals; Image reconstruction; Imaging phantoms; Medical simulation; Signal resolution;
fLanguage
English
Publisher
ieee
Conference_Titel
Nuclear Science Symposium, 1999. Conference Record. 1999 IEEE
Conference_Location
Seattle, WA
ISSN
1082-3654
Print_ISBN
0-7803-5696-9
Type
conf
DOI
10.1109/NSSMIC.1999.845841
Filename
845841
Link To Document