Your search keyword '"Huang, Cathleen"' showing total 26 results

1. Predicting mortality from AI cardiac volumes mass and coronary calcium on chest computed tomography

Author

Miller, Robert J. H., Killekar, Aditya, Shanbhag, Aakash, Bednarski, Bryan, Michalowska, Anna M., Ruddy, Terrence D., Einstein, Andrew J., Newby, David E., Lemley, Mark, Pieszko, Konrad, Van Kriekinge, Serge D., Kavanagh, Paul B., Liang, Joanna X., Huang, Cathleen, Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Published

2024

2. CT attenuation correction improves quantitative risk prediction by cardiac SPECT in obese patients

Author

Feher, Attila, Pieszko, Konrad, Shanbhag, Aakash, Lemley, Mark, Bednarski, Bryan, Miller, Robert J. H., Huang, Cathleen, Miras, Leonidas, Liu, Yi-Hwa, Sinusas, Albert J., Slomka, Piotr J., and Miller, Edward J.

Published

2024

3. Comparison of the prognostic value between quantification and visual estimation of coronary calcification from attenuation CT in patients undergoing SPECT myocardial perfusion imaging

Author

Feher, Attila, Pieszko, Konrad, Shanbhag, Aakash, Lemley, Mark, Miller, Robert JH, Huang, Cathleen, Miras, Leonidas, Liu, Yi-Hwa, Gerber, Jamie, Sinusas, Albert J., Miller, Edward J., and Slomka, Piotr J.

Published

2024

4. Unsupervised learning to characterize patients with known coronary artery disease undergoing myocardial perfusion imaging

Author

Williams, Michelle C., Bednarski, Bryan P., Pieszko, Konrad, Miller, Robert J. H., Kwiecinski, Jacek, Shanbhag, Aakash, Liang, Joanna X., Huang, Cathleen, Sharir, Tali, Dorbala, Sharmila, Di Carli, Marcelo F., Einstein, Andrew J., Sinusas, Albert J., Miller, Edward J., Bateman, Timothy M., Fish, Mathews B., Ruddy, Terrence D., Acampa, Wanda, Hauser, M. Timothy, Kaufmann, Philipp A., Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Published

2023

5. Automatic motion correction for myocardial blood flow estimation improves diagnostic performance for coronary artery disease in 18F-flurpiridaz positron emission tomography-myocardial perfusion imaging

Author

Builoff, Valerie, Huang, Cathleen, Kuronuma, Keiichiro, Wei, Chih-Chun, Fujito, Hidesato, Otaki, Yuka, Van Kriekinge, Serge D., Kavanagh, Paul, Lemley, Mark, Hyun, Mark C., Di Carli, Marcelo, Berman, Daniel S., and Slomka, Piotr J.

Published

2024

6. Clinical phenotypes among patients with normal cardiac perfusion using unsupervised learning: a retrospective observational study

Author

Miller, Robert J.H., Bednarski, Bryan P., Pieszko, Konrad, Kwiecinski, Jacek, Williams, Michelle C., Shanbhag, Aakash, Liang, Joanna X., Huang, Cathleen, Sharir, Tali, Hauser, M. Timothy, Dorbala, Sharmila, Di Carli, Marcelo F., Fish, Mathews B., Ruddy, Terrence D., Bateman, Timothy M., Einstein, Andrew J., Kaufmann, Philipp A., Miller, Edward J., Sinusas, Albert J., Acampa, Wanda, Han, Donghee, Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Published

2024

7. Correction to: Integration of coronary artery calcium scoring from CT attenuation scans by machine learning improves prediction of adverse cardiovascular events in patients undergoing SPECT/CT myocardial perfusion imaging

Author

Feher, Attila, Pieszko, Konrad, Miller, Robert, Lemley, Mark, Shanbhag, Aakash, Huang, Cathleen, Miras, Leonidas, Liu, Yi-Hwa, Sinusas, Albert J., Miller, Edward J., and Slomka, Piotr J.

Published

2023

8. Integration of coronary artery calcium scoring from CT attenuation scans by machine learning improves prediction of adverse cardiovascular events in patients undergoing SPECT/CT myocardial perfusion imaging

Author

Feher, Attila, Pieszko, Konrad, Miller, Robert, Lemley, Mark, Shanbhag, Aakash, Huang, Cathleen, Miras, Leonidas, Liu, Yi-Hwa, Sinusas, Albert J., Miller, Edward J., and Slomka, Piotr J.

Published

2023

9. Direct Risk Assessment From Myocardial Perfusion Imaging Using Explainable Deep Learning

Author

Singh, Ananya, Miller, Robert J.H., Otaki, Yuka, Kavanagh, Paul, Hauser, Michael T., Tzolos, Evangelos, Kwiecinski, Jacek, Van Kriekinge, Serge, Wei, Chih-Chun, Sharir, Tali, Einstein, Andrew J., Fish, Mathews B., Ruddy, Terrence D., Kaufmann, Philipp A., Sinusas, Albert J., Miller, Edward J., Bateman, Timothy M., Dorbala, Sharmila, Di Carli, Marcelo, Liang, Joanna X., Huang, Cathleen, Han, Donghee, Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Published

2023

10. Machine learning to predict abnormal myocardial perfusion from pre-test features

Author

Miller, Robert J. H., Hauser, M. Timothy, Sharir, Tali, Einstein, Andrew J., Fish, Mathews B., Ruddy, Terrence D., Kaufmann, Philipp A., Sinusas, Albert J., Miller, Edward J., Bateman, Timothy M., Dorbala, Sharmila, Di Carli, Marcelo, Huang, Cathleen, Liang, Joanna X., Han, Donghee, Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Published

2022

11. Artificial intelligence for disease diagnosis and risk prediction in nuclear cardiology

Author

Miller, Robert J. H., Huang, Cathleen, Liang, Joanna X., and Slomka, Piotr J.

Published

2022

12. Clinical phenotypes among patients with normal cardiac perfusion using unsupervised learning: a retrospective observational study

Author

Miller, Robert J H, Bednarski, Bryan P, Pieszko, Konrad, Kwiecinski, Jacek, Williams, Michelle C, Shanbhag, Aakash, Liang, Joanna X, Huang, Cathleen, Sharir, Tali, Hauser, M Timothy, Dorbala, Sharmila, Di Carli, Marcelo F, Fish, Mathews B, Ruddy, Terrence D, Bateman, Timothy M, Einstein, Andrew J, Kaufmann, Philipp A; https://orcid.org/0000-0002-9451-5210, Miller, Edward J, Sinusas, Albert J, Acampa, Wanda, Han, Donghee, Dey, Damini, Berman, Daniel S, Slomka, Piotr J, Miller, Robert J H, Bednarski, Bryan P, Pieszko, Konrad, Kwiecinski, Jacek, Williams, Michelle C, Shanbhag, Aakash, Liang, Joanna X, Huang, Cathleen, Sharir, Tali, Hauser, M Timothy, Dorbala, Sharmila, Di Carli, Marcelo F, Fish, Mathews B, Ruddy, Terrence D, Bateman, Timothy M, Einstein, Andrew J, Kaufmann, Philipp A; https://orcid.org/0000-0002-9451-5210, Miller, Edward J, Sinusas, Albert J, Acampa, Wanda, Han, Donghee, Dey, Damini, Berman, Daniel S, and Slomka, Piotr J

Abstract

BACKGROUND Myocardial perfusion imaging (MPI) is one of the most common cardiac scans and is used for diagnosis of coronary artery disease and assessment of cardiovascular risk. However, the large majority of MPI patients have normal results. We evaluated whether unsupervised machine learning could identify unique phenotypes among patients with normal scans and whether those phenotypes were associated with risk of death or myocardial infarction. METHODS Patients from a large international multicenter MPI registry (10 sites) with normal perfusion by expert visual interpretation were included in this cohort analysis. The training population included 9849 patients, and external testing population 12,528 patients. Unsupervised cluster analysis was performed, with separate training and external testing cohorts, to identify clusters, with four distinct phenotypes. We evaluated the clinical and imaging features of clusters and their associations with death or myocardial infarction. FINDINGS Patients in Clusters 1 and 2 almost exclusively underwent exercise stress, while patients in Clusters 3 and 4 mostly required pharmacologic stress. In external testing, the risk for Cluster 4 patients (20.2% of population, unadjusted hazard ratio [HR] 6.17, 95% confidence interval [CI] 4.64-8.20) was higher than the risk associated with pharmacologic stress (HR 3.03, 95% CI 2.53-3.63), or previous myocardial infarction (HR 1.82, 95% CI 1.40-2.36). INTERPRETATION Unsupervised learning identified four distinct phenotypes of patients with normal perfusion scans, with a significant proportion of patients at very high risk of myocardial infarction or death. Our results suggest a potential role for patient phenotyping to improve risk stratification of patients with normal imaging results. FUNDING This work was supported by the National Heart, Lung, and Blood Institute at the National Institutes of Health [R35HL161195 to PS]. The REFINE SPECT database was supported by the National Heart, Lung

Published

2024

13. Automatic Motion Correction for Myocardial Blood Flow Estimation Improves Diagnostic Performance for Coronary Artery Disease in 18F-Flurpiridaz PET-MPI

Author

Builoff, Valerie Michelle, Huang, Cathleen, Kuronuma, Keiichiro, Wei, Chih-Chun, Fujito, Hidesato, Otaki, Yuka, Van Kriekinge, Serge D., Kavanagh, Paul, Lemley, Mark, Hyun, Mark C., Berman, Daniel S., and Slomka, Piotr J.

Published

2024

14. Comparison of the prognostic value between quantification and visual estimation of coronary calcification from attenuation CT in patients undergoing SPECT myocardial perfusion imaging

Author

Feher, Attila, primary, Pieszko, Konrad, additional, Shanbhag, Aakash, additional, Lemley, Mark, additional, Miller, Robert JH, additional, Huang, Cathleen, additional, Miras, Leonidas, additional, Liu, Yi-Hwa, additional, Gerber, Jamie, additional, Sinusas, Albert J., additional, Miller, Edward J., additional, and Slomka, Piotr J., additional

Published

2023

15. Predictingmortality from AI cardiac volumes mass and coronary calcium on chest computed tomography.

Author

Miller, Robert J. H., Killekar, Aditya, Shanbhag, Aakash, Bednarski, Bryan, Michalowska, Anna M., Ruddy, Terrence D., Einstein, Andrew J., Newby, David E., Lemley, Mark, Pieszko, Konrad, Van Kriekinge, Serge D., Kavanagh, Paul B., Liang, Joanna X., Huang, Cathleen, Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Abstract

Chest computed tomography is one of the most common diagnostic tests, with 15 million scans performed annually in the United States. Coronary calcium can be visualized on these scans, but other measures of cardiac risk such as atrial and ventricular volumes have classically required administration of contrast. Here we show that a fully automated pipeline, incorporating two artificial intelligence models, automatically quantifies coronary calcium, left atrial volume, left ventricular mass, and other cardiac chamber volumes in 29,687 patients from three cohorts. The model processes chamber volumes and coronary artery calcium with an end-to-end time of ~18 s, while failing to segment only 0.1% of cases. Coronary calcium, left atrial volume, and left ventricular mass index are independently associated with all-cause and cardiovascular mortality and significantly improve risk classification compared to identification of abnormalities by a radiologist. This automated approach can be integrated into clinical workflows to improve identification of abnormalities and risk stratification, allowing physicians to improve clinical decision-making. [ABSTRACT FROM AUTHOR]

Published

2024

16. Unsupervised learning to characterize patients with known coronary artery disease undergoing myocardial perfusion imaging

Author

Williams, Michelle Claire; https://orcid.org/0000-0003-3556-2428, Bednarski, Bryan P, Pieszko, Konrad; https://orcid.org/0000-0002-5514-7750, Miller, Robert J H; https://orcid.org/0000-0003-4676-2433, Kwiecinski, Jacek, Shanbhag, Aakash, Liang, Joanna X, Huang, Cathleen, Sharir, Tali, Dorbala, Sharmila, Di Carli, Marcelo F, Einstein, Andrew J, Sinusas, Albert J; https://orcid.org/0000-0003-0972-9589, Miller, Edward J; https://orcid.org/0000-0002-2156-5962, Bateman, Timothy M, Fish, Mathews B, Ruddy, Terrence D; https://orcid.org/0000-0002-0686-5449, Acampa, Wanda, Hauser, M Timothy, Kaufmann, Philipp A; https://orcid.org/0000-0002-9451-5210, Dey, Damini; https://orcid.org/0000-0003-2236-6970, Berman, Daniel S; https://orcid.org/0000-0002-3793-9578, Slomka, Piotr J; https://orcid.org/0000-0002-6110-938X, Williams, Michelle Claire; https://orcid.org/0000-0003-3556-2428, Bednarski, Bryan P, Pieszko, Konrad; https://orcid.org/0000-0002-5514-7750, Miller, Robert J H; https://orcid.org/0000-0003-4676-2433, Kwiecinski, Jacek, Shanbhag, Aakash, Liang, Joanna X, Huang, Cathleen, Sharir, Tali, Dorbala, Sharmila, Di Carli, Marcelo F, Einstein, Andrew J, Sinusas, Albert J; https://orcid.org/0000-0003-0972-9589, Miller, Edward J; https://orcid.org/0000-0002-2156-5962, Bateman, Timothy M, Fish, Mathews B, Ruddy, Terrence D; https://orcid.org/0000-0002-0686-5449, Acampa, Wanda, Hauser, M Timothy, Kaufmann, Philipp A; https://orcid.org/0000-0002-9451-5210, Dey, Damini; https://orcid.org/0000-0003-2236-6970, Berman, Daniel S; https://orcid.org/0000-0002-3793-9578, and Slomka, Piotr J; https://orcid.org/0000-0002-6110-938X

Abstract

PURPOSE Patients with known coronary artery disease (CAD) comprise a heterogenous population with varied clinical and imaging characteristics. Unsupervised machine learning can identify new risk phenotypes in an unbiased fashion. We use cluster analysis to risk-stratify patients with known CAD undergoing single-photon emission computed tomography (SPECT) myocardial perfusion imaging (MPI). METHODS From 37,298 patients in the REFINE SPECT registry, we identified 9221 patients with known coronary artery disease. Unsupervised machine learning was performed using clinical (23), acquisition (17), and image analysis (24) parameters from 4774 patients (internal cohort) and validated with 4447 patients (external cohort). Risk stratification for all-cause mortality was compared to stress total perfusion deficit (< 5%, 5-10%, ≥10%). RESULTS Three clusters were identified, with patients in Cluster 3 having a higher body mass index, more diabetes mellitus and hypertension, and less likely to be male, have dyslipidemia, or undergo exercise stress imaging (p < 0.001 for all). In the external cohort, during median follow-up of 2.6 [0.14, 3.3] years, all-cause mortality occurred in 312 patients (7%). Cluster analysis provided better risk stratification for all-cause mortality (Cluster 3: hazard ratio (HR) 5.9, 95% confidence interval (CI) 4.0, 8.6, p < 0.001; Cluster 2: HR 3.3, 95% CI 2.5, 4.5, p < 0.001; Cluster 1, reference) compared to stress total perfusion deficit (≥10%: HR 1.9, 95% CI 1.5, 2.5 p < 0.001; < 5%: reference). CONCLUSIONS Our unsupervised cluster analysis in patients with known CAD undergoing SPECT MPI identified three distinct phenotypic clusters and predicted all-cause mortality better than ischemia alone.

Published

2023

17. Automated Motion Correction for Myocardial Blood Flow Measurements and Diagnostic Performance of 82Rb PET Myocardial Perfusion Imaging.

Author

Keiichiro Kuronuma, Chih-Chun Wei, Singh, Ananya, Lemley, Mark, Hayes, Sean W., Otaki, Yuka, Hyun, Mark C., Van Kriekinge, Serge D., Kavanagh, Paul, Huang, Cathleen, Donghee Han, Dey, Damini, Berman, Daniel S., and Slomka, Piotr J.

Published

2024

18. Deep Learning-based Attenuation Correction Improves Diagnostic Accuracy of Cardiac SPECT

Author

Shanbhag, Aakash D, Miller, Robert J H, Pieszko, Konrad, Lemley, Mark, Kavanagh, Paul, Feher, Attila, Miller, Edward J, Sinusas, Albert J, Kaufmann, Philipp A, Han, Donghee, Huang, Cathleen, Liang, Joanna X, Berman, Daniel S, Dey, Damini, Slomka, Piotr J, and University of Zurich

Subjects

610 Medicine & health, 10181 Clinic for Nuclear Medicine

Published

2023

19. Deep Learning Coronary Artery Calcium Scores from SPECT/CT Attenuation Maps Improve Prediction of Major Adverse Cardiac Events

Author

Miller, Robert J.H., primary, Pieszko, Konrad, additional, Shanbhag, Aakash, additional, Feher, Attila, additional, Lemley, Mark, additional, Killekar, Aditya, additional, Kavanagh, Paul B., additional, Van Kriekinge, Serge D., additional, Liang, Joanna X., additional, Huang, Cathleen, additional, Miller, Edward J., additional, Bateman, Timothy, additional, Berman, Daniel S., additional, Dey, Damini, additional, and Slomka, Piotr J., additional

Published

2022

20. Integration of coronary artery calcium scoring from CT attenuation scans by machine learning improves prediction of adverse cardiovascular events in patients undergoing SPECT/CT myocardial perfusion imaging

Author

Feher, Attila, primary, Pieszko, Konrad, additional, Miller, Robert, additional, Lemley, Mark, additional, Shanbhag, Aakash, additional, Huang, Cathleen, additional, Miras, Leonidas, additional, Liu, Yi-Hwa, additional, Sinusas, Albert J., additional, Miller, Edward J., additional, and Slomka, Piotr J., additional

Published

2022

21. Deep Learning-based Attenuation Correction Improves Diagnostic Accuracy of Cardiac SPECT

Author

Shanbhag, Aakash D., primary, Miller, Robert J.H., additional, Pieszko, Konrad, additional, Lemley, Mark, additional, Kavanagh, Paul, additional, Feher, Attila, additional, Miller, Edward J., additional, Sinusas, Albert J., additional, Kaufmann, Philipp A., additional, Han, Donghee, additional, Huang, Cathleen, additional, Liang, Joanna X., additional, Berman, Daniel S., additional, Dey, Damini, additional, and Slomka, Piotr J., additional

Published

2022

22. Machine learning to predict abnormal myocardial perfusion from pre-test features

Author

Miller, Robert J H, Hauser, M Timothy, Sharir, Tali, Einstein, Andrew J, Fish, Mathews B, Ruddy, Terrence D, Kaufmann, Philipp A, Sinusas, Albert J, Miller, Edward J, Bateman, Timothy M, Dorbala, Sharmila, Di Carli, Marcelo, Huang, Cathleen, Liang, Joanna X, Han, Donghee, Dey, Damini, Berman, Daniel S, Slomka, Piotr J, Miller, Robert J H, Hauser, M Timothy, Sharir, Tali, Einstein, Andrew J, Fish, Mathews B, Ruddy, Terrence D, Kaufmann, Philipp A, Sinusas, Albert J, Miller, Edward J, Bateman, Timothy M, Dorbala, Sharmila, Di Carli, Marcelo, Huang, Cathleen, Liang, Joanna X, Han, Donghee, Dey, Damini, Berman, Daniel S, and Slomka, Piotr J

Abstract

BACKGROUND Accurately predicting which patients will have abnormal perfusion on MPI based on pre-test clinical information may help physicians make test selection decisions. We developed and validated a machine learning (ML) model for predicting abnormal perfusion using pre-test features. METHODS We included consecutive patients who underwent SPECT MPI, with 20,418 patients from a multi-center (5 sites) international registry in the training population and 9019 patients (from 2 separate sites) in the external testing population. The ML (extreme gradient boosting) model utilized 30 pre-test features to predict the presence of abnormal myocardial perfusion by expert visual interpretation. RESULTS In external testing, the ML model had higher prediction performance for abnormal perfusion (area under receiver-operating characteristic curve [AUC] 0.762, 95% CI 0.750-0.774) compared to the clinical CAD consortium (AUC 0.689) basic CAD consortium (AUC 0.657), and updated Diamond-Forrester models (AUC 0.658, p < 0.001 for all). Calibration (validation of the continuous risk prediction) was superior for the ML model (Brier score 0.149) compared to the other models (Brier score 0.165 to 0.198, all p < 0.001). CONCLUSION ML can predict abnormal myocardial perfusion using readily available pre-test information. This model could be used to help guide physician decisions regarding non-invasive test selection.

Published

2022

23. Deep Learning Coronary Artery Calcium Scores from SPECT/CT Attenuation Maps Improve Prediction of Major Adverse Cardiac Events.

Author

Miller, Robert J. H., Pieszko, Konrad, Shanbhag, Aakash, Feher, Attila, Lemley, Mark, Killekar, Aditya, Kavanagh, Paul B., Van Kriekinge, Serge D., Liang, Joanna X., Huang, Cathleen, Miller, Edward J., Bateman, Timothy, Berman, Daniel S., Dey, Damini, and Slomka, Piotr J.

Published

2023

24. Deep Learning-Based Attenuation Correction Improves Diagnostic Accuracy of Cardiac SPECT.

Author

Shanbhag, Aakash D., Miller, Robert J. H., Pieszko, Konrad, Lemley, Mark, Kavanagh, Paul, Feher, Attila, Miller, Edward J., Sinusas, Albert J., Kaufmann, Philipp A., Donghee Han, Huang, Cathleen, Liang, Joanna X., Berman, Daniel S., Dey, Damini, and Slomka, Piotr J.

Published

2023

25. Perivascular Adipose Tissue Surrounding Healthy and Diseased Human Aorta Represent Two Distinct Populations of Adipocytes

Author

Malka, Kimberly T., primary, Clum, Penny, additional, Tero, Benjamin, additional, Huang, Cathleen, additional, Vary, Calvin, additional, and Liaw, Lucy, additional

Published

2021

26. Automated Motion Correction for Myocardial Blood Flow Measurements and Diagnostic Performance of 82 Rb PET Myocardial Perfusion Imaging.

Author

Kuronuma K, Wei CC, Singh A, Lemley M, Hayes SW, Otaki Y, Hyun MC, Van Kriekinge SD, Kavanagh P, Huang C, Han D, Dey D, Berman DS, and Slomka PJ

Subjects

Humans, Coronary Circulation, Coronary Angiography methods, Positron-Emission Tomography methods, Myocardial Perfusion Imaging methods, Coronary Artery Disease diagnostic imaging, Fractional Flow Reserve, Myocardial

Abstract

Motion correction (MC) affects myocardial blood flow (MBF) measurements in 82 Rb PET myocardial perfusion imaging (MPI); however, frame-by-frame manual MC of dynamic frames is time-consuming. This study aims to develop an automated MC algorithm for time-activity curves used in compartmental modeling and compare the predictive value of MBF with and without automated MC for significant coronary artery disease (CAD). Methods: In total, 565 patients who underwent PET-MPI were considered. Patients without angiographic findings were split into training ( n = 112) and validation ( n = 112) groups. The automated MC algorithm used simplex iterative optimization of a count-based cost function and was developed using the training group. MBF measurements with automated MC were compared with those with manual MC in the validation group. In a separate cohort, 341 patients who underwent PET-MPI and invasive coronary angiography were enrolled in the angiographic group. The predictive performance in patients with significant CAD (≥70% stenosis) was compared between MBF measurements with and without automated MC. Results: In the validation group ( n = 112), MBF measurements with automated and manual MC showed strong correlations ( r = 0.98 for stress MBF and r = 0.99 for rest MBF). The automatic MC took less time than the manual MC (<12 s vs. 10 min per case). In the angiographic group ( n = 341), MBF measurements with automated MC decreased significantly compared with those without (stress MBF, 2.16 vs. 2.26 mL/g/min; rest MBF, 1.12 vs. 1.14 mL/g/min; MFR, 2.02 vs. 2.10; all P < 0.05). The area under the curve (AUC) for the detection of significant CAD by stress MBF with automated MC was higher than that without (AUC, 95% CI, 0.76 [0.71-0.80] vs. 0.73 [0.68-0.78]; P < 0.05). The addition of stress MBF with automated MC to the model with ischemic total perfusion deficit showed higher diagnostic performance for detection of significant CAD (AUC, 95% CI, 0.82 [0.77-0.86] vs. 0.78 [0.74-0.83]; P = 0.022), but the addition of stress MBF without MC to the model with ischemic total perfusion deficit did not reach significance (AUC, 95% CI, 0.81 [0.76-0.85] vs. 0.78 [0.74-0.83]; P = 0.067). Conclusion: Automated MC on 82 Rb PET-MPI can be performed rapidly with excellent agreement with experienced operators. Stress MBF with automated MC showed significantly higher diagnostic performance than without MC., (© 2024 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2024