Comparison of positional artifacts in myocardial perfusion imaging in supine and semi-reclining position using dedicated D-SPECT cardiac camera: validation using CT based attenuation correction

Germano G(2007)Attenuation artifact, attenuation correction, and the future of myocardial perfusion SPECT J Nucl Cardiol 14 153-308

Mouden M(2016)Diagnostic accuracy of cadmium-zinc-telluride-based myocardial perfusion SPECT: Impact of attenuation correction using a co-registered external computed tomography Eur Heart J Cardiovasc Imaging 17 1036-290

Timmer JR(2009)Clinical evaluation of a low-dose, X-ray-based transmission imaging for attenuation correction of SPECT myocardial perfusion images J Nucl Med 50 598-1731

Ottervanger JP(2017)Comparison between prone and upright imaging of the inferior wall using 201TlCl myocardial perfusion SPECT J Nucl Med Technol 45 304-275

Reiffers S(2011)Soft tissue attenuation patterns in stress myocardial perfusion SPECT images: A comparison between supine and upright acquisition systems J Nucl Cardiol 18 281-736

Oostdijk AH(2010)Quantitative upright–supine high-speed SPECT myocardial perfusion imaging for detection of coronary artery disease: Correlation with invasive coronary angiography J Nucl Med 51 1724-639

Knollema S(2009)Supine and semi-upright myocardial perfusion imaging (MPI) with a novel dedicated cardiac camera J Nucl Med 50 1132-23

Niimi T(2015)Quantitative high-efficiency cadmium-zinc-telluride SPECT with dedicated parallel-hole collimation system in obese patients: Results of a multi-center study J Nucl Cardiol 22 266-310

Nanasato M(2020)Automated quantitative analysis of CZT SPECT stratifies cardiovascular risk in the obese population: Analysis of the REFINE SPECT registry J Nucl Cardiol 29 727-27

Sugimoto M(2016)ASNC imaging guidelines for SPECT nuclear cardiology procedures: Stress, protocols, and tracers J Nucl Cardiol 23 606-1159

Germano G(2007)Attenuation artifact, attenuation correction, and the future of myocardial perfusion SPECT J Nucl Cardiol 14 153-308

Mouden M(2016)Diagnostic accuracy of cadmium-zinc-telluride-based myocardial perfusion SPECT: Impact of attenuation correction using a co-registered external computed tomography Eur Heart J Cardiovasc Imaging 17 1036-290

Timmer JR(2009)Clinical evaluation of a low-dose, X-ray-based transmission imaging for attenuation correction of SPECT myocardial perfusion images J Nucl Med 50 598-1731

Ottervanger JP(2017)Comparison between prone and upright imaging of the inferior wall using 201TlCl myocardial perfusion SPECT J Nucl Med Technol 45 304-275

Reiffers S(2011)Soft tissue attenuation patterns in stress myocardial perfusion SPECT images: A comparison between supine and upright acquisition systems J Nucl Cardiol 18 281-736

Oostdijk AH(2010)Quantitative upright–supine high-speed SPECT myocardial perfusion imaging for detection of coronary artery disease: Correlation with invasive coronary angiography J Nucl Med 51 1724-639

Knollema S(2009)Supine and semi-upright myocardial perfusion imaging (MPI) with a novel dedicated cardiac camera J Nucl Med 50 1132-23

Niimi T(2015)Quantitative high-efficiency cadmium-zinc-telluride SPECT with dedicated parallel-hole collimation system in obese patients: Results of a multi-center study J Nucl Cardiol 22 266-310

Nanasato M(2020)Automated quantitative analysis of CZT SPECT stratifies cardiovascular risk in the obese population: Analysis of the REFINE SPECT registry J Nucl Cardiol 29 727-27

Sugimoto M(2016)ASNC imaging guidelines for SPECT nuclear cardiology procedures: Stress, protocols, and tracers J Nucl Cardiol 23 606-1159