Deep Learning Analysis of Upright-Supine High-Efficiency SPECT Myocardial Perfusion Imaging for Prediction of Obstructive Coronary Artery Disease: A Multicenter Study

Combined analysis of SPECT myocardial perfusion imaging (MPI) performed with a solid-state camera on patients in 2 positions (semiupright, supine) is routinely used to mitigate attenuation artifacts. We evaluated the prediction of obstructive disease from combined analysis of semiupright and supine stress MPI by deep learning (DL) as compared with standard combined total perfusion deficit (TPD). Methods: 1,160 patients without known coronary artery disease (64% male) were studied. Patients underwent stress 99mTc-sestamibi MPI with new-generation solid-state SPECT scanners in 4 different centers. All patients had on-site clinical reads and invasive coronary angiography correlations within 6 mo of MPI. Obstructive disease was defined as at least 70% narrowing of the 3 major coronary arteries and at least 50% for the left main coronary artery. Images were quantified at Cedars-Sinai. The left ventricular myocardium was segmented using standard clinical nuclear cardiology software. The contour placement was verified by an experienced technologist. Combined stress TPD was computed using sex- and camera-specific normal limits. DL was trained using polar distributions of normalized radiotracer counts, hypoperfusion defects, and hypoperfusion severities and was evaluated for prediction of obstructive disease in a novel leave-one-center-out cross-validation procedure equivalent to external validation. During the validation procedure, 4 DL models were trained using data from 3 centers and then evaluated on the 1 center left aside. Predictions for each center were merged to have an overall estimation of the multicenter performance. Results: 718 (62%) patients and 1,272 of 3,480 (37%) arteries had obstructive disease. The area under the receiver operating characteristics curve for prediction of disease on a per-patient and per-vessel basis by DL was higher than for combined TPD (per-patient, 0.81 vs. 0.78; per-vessel, 0.77 vs. 0.73; P < 0.001). With the DL cutoff set to exhibit the same specificity as the standard cutoff for combined TPD, per-patient sensitivity improved from 61.8% (TPD) to 65.6% (DL) (P < 0.05), and per-vessel sensitivity improved from 54.6% (TPD) to 59.1% (DL) (P < 0.01). With the threshold matched to the specificity of a normal clinical read (56.3%), DL had a sensitivity of 84.8%, versus 82.6% for an on-site clinical read (P = 0.3). Conclusion: DL improves automatic interpretation of MPI as compared with current quantitative methods.

[1]  Guido Germano,et al.  Comparison of Fully Automated Computer Analysis and Visual Scoring for Detection of Coronary Artery Disease from Myocardial Perfusion SPECT in a Large Population , 2013, The Journal of Nuclear Medicine.

[2]  Damini Dey,et al.  Prognostic Value of Combined Clinical and Myocardial Perfusion Imaging Data Using Machine Learning. , 2017, JACC. Cardiovascular imaging.

[3]  D. Berman,et al.  Quantitative Upright–Supine High-Speed SPECT Myocardial Perfusion Imaging for Detection of Coronary Artery Disease: Correlation with Invasive Coronary Angiography , 2010, The Journal of Nuclear Medicine.

[4]  D. Berman,et al.  Automated quantification of myocardial perfusion SPECT using simplified normal limits , 2004, Journal of nuclear cardiology : official publication of the American Society of Nuclear Cardiology.

[5]  Piotr J. Slomka,et al.  Quantitation in gated perfusion SPECT imaging: The Cedars-Sinai approach , 2007, Journal of nuclear cardiology : official publication of the American Society of Nuclear Cardiology.

[6]  Joshua E. Lewis,et al.  Predicting clinical outcomes from large scale cancer genomic profiles with deep survival models , 2017, Scientific Reports.

[7]  Li Fei-Fei,et al.  ImageNet: A large-scale hierarchical image database , 2009, CVPR.

[8]  E. DeLong,et al.  Comparing the areas under two or more correlated receiver operating characteristic curves: a nonparametric approach. , 1988, Biometrics.

[9]  Amit Ramesh,et al.  Automated Quality Control for Segmentation of Myocardial Perfusion SPECT , 2009, Journal of Nuclear Medicine.

[10]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[11]  Jim Patton,et al.  A Novel High-Sensitivity Rapid-Acquisition Single-Photon Cardiac Imaging Camera , 2009, Journal of Nuclear Medicine.

[12]  D E Grobbee,et al.  External validation is necessary in prediction research: a clinical example. , 2003, Journal of clinical epidemiology.

[13]  Frank E. Harrell,et al.  Prediction models need appropriate internal, internal-external, and external validation. , 2016, Journal of clinical epidemiology.

[14]  Guido Germano,et al.  Combined supine and prone quantitative myocardial perfusion SPECT: method development and clinical validation in patients with no known coronary artery disease. , 2006, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[15]  D. Dey,et al.  Deep Learning for Prediction of Obstructive Disease From Fast Myocardial Perfusion SPECT: A Multicenter Study. , 2018, JACC. Cardiovascular imaging.

[16]  Trevor Darrell,et al.  Caffe: Convolutional Architecture for Fast Feature Embedding , 2014, ACM Multimedia.

[17]  Geoffrey E. Hinton,et al.  Deep Learning , 2015, Nature.

[18]  D. Dey,et al.  Automatic Valve Plane Localization in Myocardial Perfusion SPECT/CT by Machine Learning: Anatomic and Clinical Validation , 2017, The Journal of Nuclear Medicine.

[19]  Guido Germano,et al.  Advances in technical aspects of myocardial perfusion SPECT imaging , 2009, Journal of Nuclear Cardiology.

[20]  Piotr J. Slomka,et al.  Improved accuracy of myocardial perfusion SPECT for detection of coronary artery disease by machine learning in a large population , 2013, Journal of Nuclear Cardiology.

[21]  Andrew J Einstein,et al.  Effects of radiation exposure from cardiac imaging: how good are the data? , 2012, Journal of the American College of Cardiology.

[22]  Piotr J. Slomka,et al.  Rationale and design of the REgistry of Fast Myocardial Perfusion Imaging with NExt generation SPECT (REFINE SPECT) , 2018, Journal of Nuclear Cardiology.

[23]  Piotr J. Slomka,et al.  Advances in Nuclear Cardiac Instrumentation with a View Towards Reduced Radiation Exposure , 2012, Current Cardiology Reports.