BACKGROUND: We have previously developed a new method for quantitative assessment of left ventricular (LV) volumes and ejection fraction (EF) from electrocardiography-gated single photon emission computed tomography (SPECT). The aims of this study were to present the methodology, to validate the gated SPECT cardiac quantification (GSCQ) method in phantoms and patients, and to determine normal values of LVEF. METHODS AND RESULTS: A simple thresholding technique was used to generate binary images from nongated SPECT images. The K-means cluster classification algorithm was used to separate the LV region from non-LV regions on the binary images. A count- and geometry-based algorithm was applied to define endocardial and epicardial boundaries for calculation of LV volumes and LVEF. Overall correlation between GSCQ-quantified volumes and actual phantom volumes was good ( r = 0.97 and standard error of estimation (SEE) = 9.99 mL for normal phantoms, r = 0.99 and SEE = 6.97 mL for phantoms with defects). In patient studies, LVEF derived by GSCQ from SPECT and from equilibrium radionuclide angiography also showed good correlation ( r = 0.90 and SEE = 6.2%). The lower limit of normal LVEF from 8-frame gated SPECT by use of GSCQ was 45%. Quantification of LVEF by the GSCQ method was highly producible and was not significantly affected by the presence of myocardial perfusion defects or intense gastrointestinal activity. CONCLUSIONS: The GSCQ method provides reliable and consistent assessments of LV volumes and EF. This methodology is less affected by intense gastrointestinal activity than other methods.
BACKGROUND: We have previously developed a new method for quantitative assessment of left ventricular (LV) volumes and ejection fraction (EF) from electrocardiography-gated single photon emission computed tomography (SPECT). The aims of this study were to present the methodology, to validate the gated SPECT cardiac quantification (GSCQ) method in phantoms and patients, and to determine normal values of LVEF. METHODS AND RESULTS: A simple thresholding technique was used to generate binary images from nongated SPECT images. The K-means cluster classification algorithm was used to separate the LV region from non-LV regions on the binary images. A count- and geometry-based algorithm was applied to define endocardial and epicardial boundaries for calculation of LV volumes and LVEF. Overall correlation between GSCQ-quantified volumes and actual phantom volumes was good ( r = 0.97 and standard error of estimation (SEE) = 9.99 mL for normal phantoms, r = 0.99 and SEE = 6.97 mL for phantoms with defects). In patient studies, LVEF derived by GSCQ from SPECT and from equilibrium radionuclide angiography also showed good correlation ( r = 0.90 and SEE = 6.2%). The lower limit of normal LVEF from 8-frame gated SPECT by use of GSCQ was 45%. Quantification of LVEF by the GSCQ method was highly producible and was not significantly affected by the presence of myocardial perfusion defects or intense gastrointestinal activity. CONCLUSIONS: The GSCQ method provides reliable and consistent assessments of LV volumes and EF. This methodology is less affected by intense gastrointestinal activity than other methods.
Authors: E Vallejo; D P Dione; W L Bruni; R T Constable; P P Borek; J P Soares; J G Carr; S G Condos; F J Wackers; A J Sinusas Journal: J Nucl Med Date: 2000-05 Impact factor: 10.057
Authors: Doo Sun Sim; Myung Ho Jeong; Ho Chun Song; Jahae Kim; Ari Chong; Hee Seung Bom; In Seok Jeong; Sang Gi Oh; Jong Min Kim; Dae Sung Park; Jung Ha Kim; Kyung Seob Lim; Min Suk Kim; Shi Hyun Ryu; Hyun Kuk Kim; Sung Soo Kim; Su Young Jang; Jae Yeong Cho; Hae Chang Jeong; Ki Hong Lee; Keun Ho Park; Nam Sik Yoon; Hyun Ju Yoon; Kye Hun Kim; Young Joon Hong; Hyung Wook Park; Ju Han Kim; Youngkeun Ahn; Jeong Gwan Cho; Jong Chun Park; Jung Chaee Kang Journal: J Korean Med Sci Date: 2014-12-23 Impact factor: 2.153