UNLABELLED: SPECT can provide valuable diagnostic and treatment response information in large-scale multicenter clinical trials. However, SPECT has been limited in providing consistent quantitative functional parametric values across the centers, largely because of a lack of standardized procedures to correct for attenuation and scatter. Recently, a novel software package has been developed to reconstruct quantitative SPECT images and assess cerebral blood flow (CBF) at rest and after acetazolamide challenge from a single SPECT session. This study was aimed at validating this technique at different institutions with a variety of SPECT devices and imaging protocols. METHODS: Twelve participating institutions obtained a series of SPECT scans on physical phantoms and clinical patients. The phantom experiments included the assessment of septal penetration for each collimator used and of the accuracy of the reconstructed images. Clinical studies were divided into 3 protocols, including intrainstitutional reproducibility, a comparison with PET, and rest-rest study consistency. The results from 46 successful studies were analyzed. RESULTS: Activity concentration estimation (Bq/mL) in the reconstructed SPECT images of a uniform cylindric phantom showed an interinstitution variation of ±5.1%, with a systematic underestimation of concentration by 12.5%. CBF values were reproducible both at rest and after acetazolamide on the basis of repeated studies in the same patient (mean ± SD difference, -0.4 ± 5.2 mL/min/100 g, n = 44). CBF values were also consistent with those determined using PET (-6.1 ± 5.1 mL/min/100 g, n = 6). CONCLUSION: This study demonstrates that SPECT can quantitatively provide physiologic functional images of rest and acetazolamide challenge CBF, using a quantitative reconstruction software package.
UNLABELLED: SPECT can provide valuable diagnostic and treatment response information in large-scale multicenter clinical trials. However, SPECT has been limited in providing consistent quantitative functional parametric values across the centers, largely because of a lack of standardized procedures to correct for attenuation and scatter. Recently, a novel software package has been developed to reconstruct quantitative SPECT images and assess cerebral blood flow (CBF) at rest and after acetazolamide challenge from a single SPECT session. This study was aimed at validating this technique at different institutions with a variety of SPECT devices and imaging protocols. METHODS: Twelve participating institutions obtained a series of SPECT scans on physical phantoms and clinical patients. The phantom experiments included the assessment of septal penetration for each collimator used and of the accuracy of the reconstructed images. Clinical studies were divided into 3 protocols, including intrainstitutional reproducibility, a comparison with PET, and rest-rest study consistency. The results from 46 successful studies were analyzed. RESULTS: Activity concentration estimation (Bq/mL) in the reconstructed SPECT images of a uniform cylindric phantom showed an interinstitution variation of ±5.1%, with a systematic underestimation of concentration by 12.5%. CBF values were reproducible both at rest and after acetazolamide on the basis of repeated studies in the same patient (mean ± SD difference, -0.4 ± 5.2 mL/min/100 g, n = 44). CBF values were also consistent with those determined using PET (-6.1 ± 5.1 mL/min/100 g, n = 6). CONCLUSION: This study demonstrates that SPECT can quantitatively provide physiologic functional images of rest and acetazolamide challenge CBF, using a quantitative reconstruction software package.
Authors: Y Uchihashi; K Hosoda; I Zimine; A Fujita; M Fujii; K Sugimura; E Kohmura Journal: AJNR Am J Neuroradiol Date: 2011-07-14 Impact factor: 3.825
Authors: Brian E Zimmerman; Darko Grošev; Irène Buvat; Marco A Coca Pérez; Eric C Frey; Alan Green; Anchali Krisanachinda; Michael Lassmann; Michael Ljungberg; Lorena Pozzo; Kamila Afroj Quadir; Mariella A Terán Gretter; Johann Van Staden; Gian Luca Poli Journal: Z Med Phys Date: 2016-04-19 Impact factor: 4.820
Authors: Ralph Buchert; Andreas Kluge; Livia Tossici-Bolt; John Dickson; Marcus Bronzel; Catharina Lange; Susanne Asenbaum; Jan Booij; L Özlem Atay Kapucu; Claus Svarer; Pierre-Malick Koulibaly; Flavio Nobili; Marco Pagani; Osama Sabri; Terez Sera; Klaus Tatsch; Thierry Vander Borght; Koen Van Laere; Andrea Varrone; Hidehiro Iida Journal: Eur J Nucl Med Mol Imaging Date: 2016-01-27 Impact factor: 9.236