Region-based Efficiency Correction for the High-Resolution quad-HIDAC PET scanner

The very high resolution quad-HIDAC PET scanner has four detector banks each with four planar high density avalanche chambers, capable of collecting billions of lines-of-response (LORs), with very high spatial resolution, good absolute sensitivity and a large field of view (170 mm times 170 mm times...

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Main Authors: Maynez, L.O., Julyan, P.J., Hastings, D.L., Reader, A.J.
Format: Conference Proceeding
Language:English
Subjects:
Chemical analysis
Degradation
Detectors
Event detection
Geometry
Image reconstruction
Matrix converters
Positron emission tomography
Spatial resolution
Transmission line matrix methods
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Julyan, P.J.
Hastings, D.L.
Reader, A.J.
description The very high resolution quad-HIDAC PET scanner has four detector banks each with four planar high density avalanche chambers, capable of collecting billions of lines-of-response (LORs), with very high spatial resolution, good absolute sensitivity and a large field of view (170 mm times 170 mm times 280 mm). However, it is crucial to correct for degrading factors introduced by the scanner's geometry and detection. A plane converter efficiency estimation method based on acceptance regions is presented, in which it is possible to represent a plane converter as a set of detection efficiency areas. LORs registered in a particular region in coincidence with another in the opposite plane converter are registered in a square array named a cooccurrence matrix, which is the basis of the method. The reciprocal of these factors are used as a multiplicative correction within the list-mode EM algorithm, event by event. A methodology to obtain the system-geometric correction factors is described and included within the reconstruction process as a normalisation component. Reconstructed images from a uniform 18 F cylinder source (3 cm diameter, 5 cm length) and a 68 Ge line source (15.5 cm length), were used to assess the region-efficiency and system-geometry correction.
doi_str_mv 10.1109/NSSMIC.2006.356511
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subjects Chemical analysis
Degradation
Detectors
Event detection
Geometry
Image reconstruction
Matrix converters
Positron emission tomography
Spatial resolution
Transmission line matrix methods
title Region-based Efficiency Correction for the High-Resolution quad-HIDAC PET scanner
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