S R Meikle1, B F Hutton, D L Bailey. 1. Department of Nuclear Medicine, Royal Prince Alfred Hospital, Sydney, Australia.
Abstract
UNLABELLED: A method of scatter compensation has been developed that incorporates planar transmission measurements in the estimation of photopeak scatter in SPECT. METHODS: The scatter distribution is first estimated by convolving the planar projections with a monoexponential scatter function. The number of scattered events that subsequently reach the detector as a proportion of total events (i.e., scatter fraction) is then determined for each point in the projections based on narrow-beam transmission values, obtained using an external source. The assumptions of the method were tested using 99mTc and 201Tl point and line sources. The quantitative and qualitative impact of transmission-dependent scatter correction was assessed in realistic phantom experiments simulating blood-pool, lung and myocardial perfusion studies. RESULTS: The method accurately predicts the scatter distribution from 99mTc and 201Tl line sources in a phantom with variable density. Reconstructed counts are artificially enhanced in regions of high tissue density when scattered events are not removed from the projections prior to attenuation correction. Using convolution-subtraction with a constant scatter fraction (k = 0.4), scatter is underestimated in the heart and overestimated in the lungs, whereas transmission-dependent scatter correction enables activity to be quantified with > or = 95% accuracy in heart and lung regions. CONCLUSION: We conclude that incorporating transmission data enables accurate scatter compensation in objects with nonuniform density.
UNLABELLED: A method of scatter compensation has been developed that incorporates planar transmission measurements in the estimation of photopeak scatter in SPECT. METHODS: The scatter distribution is first estimated by convolving the planar projections with a monoexponential scatter function. The number of scattered events that subsequently reach the detector as a proportion of total events (i.e., scatter fraction) is then determined for each point in the projections based on narrow-beam transmission values, obtained using an external source. The assumptions of the method were tested using 99mTc and 201Tl point and line sources. The quantitative and qualitative impact of transmission-dependent scatter correction was assessed in realistic phantom experiments simulating blood-pool, lung and myocardial perfusion studies. RESULTS: The method accurately predicts the scatter distribution from 99mTc and 201Tl line sources in a phantom with variable density. Reconstructed counts are artificially enhanced in regions of high tissue density when scattered events are not removed from the projections prior to attenuation correction. Using convolution-subtraction with a constant scatter fraction (k = 0.4), scatter is underestimated in the heart and overestimated in the lungs, whereas transmission-dependent scatter correction enables activity to be quantified with > or = 95% accuracy in heart and lung regions. CONCLUSION: We conclude that incorporating transmission data enables accurate scatter compensation in objects with nonuniform density.
Authors: Leighton R Barnden; Rochelle L Hatton; Setayesh Behin-Ain; Brian F Hutton; Elizabeth A Goble Journal: Eur J Nucl Med Mol Imaging Date: 2003-11-29 Impact factor: 9.236
Authors: Grant T Gullberg; Bryan W Reutter; Arkadiusz Sitek; Jonathan S Maltz; Thomas F Budinger Journal: Phys Med Biol Date: 2010-09-22 Impact factor: 3.609