Deep Learning for Prediction of Obstructive Disease From Fast Myocardial Perfusion SPECT

Betancur, Julián; Commandeur, Frédéric; Motlagh, Mahsaw; Sharir, Tali; Einstein, Andrew J.; Bokhari, Sabahat; Fish, Mathews B.; Ruddy, Terrence D.; Kaufmann, Philipp A.; Sinusas, Albert J.; Miller, Edward J.; Bateman, Timothy M.; Dorbala, Sharmila; Carli, Marcelo Di; Germano, Guido; Otaki, Yuka; Tamarappoo, Balaji; Dey, Damini; Berman, Daniel S.; Slomka, Piotr J.

doi:10.1016/j.jcmg.2018.01.020

Cited by 262 publications

(172 citation statements)

References 31 publications

Supporting

Mentioning

169

Contrasting

Unclassified

Order By: Relevance

“…Since this registry includes all the imaging datasets, direct analysis of images from the registry in new projects is possible. In one very recent report, Betancur et al developed a deep learning artificial intelligence model for automatic prediction of obstructive disease utilizing data directly from the registry (13). Further analyses can be conducted aimed to describe end-points and disease per subpopulations (e.g., gender and obesity).…”

Section: Discussionmentioning

confidence: 99%

Rationale and design of the REgistry of Fast Myocardial Perfusion Imaging with NExt generation SPECT (REFINE SPECT)

Slomka

Betancur

Liang

et al. 2020

Journal of Nuclear Cardiology

Self Cite

View full text Add to dashboard Cite

show abstract

Section: Discussionmentioning

confidence: 99%

Rationale and design of the REgistry of Fast Myocardial Perfusion Imaging with NExt generation SPECT (REFINE SPECT)

Slomka

Betancur

Liang

et al. 2020

Journal of Nuclear Cardiology

Self Cite

View full text Add to dashboard Cite

show abstract

“…Additionally these models are stochastic, meaning that every time a network fits the same data but with different initial weights different features are learned. More specifically, in an extensive review [231] of whether the problem of LV/RV segmentation is solved the authors state that although the classification aspect of the problem achieves near perfect results the use of a 'diagnostic black box' can not be integrated in the clinical practice. Miotto et al [240] mention interpretability as one of the main challenges facing the clinical application of deep learning to healthcare.…”

Section: Discussion and Future Directionsmentioning

confidence: 99%

“…Method Application/Notes a CT Lessman 2016 [195] CNN detect coronary calcium using three independently trained CNNs Shadmi 2018 [196] DenseNet compared DenseNet and u-net for detecting coronary calcium Cano 2018 [197] CNN 3D regression CNN for calculation of the Agatston score Wolterink 2016 [198] CNN detect coronary calcium using three CNNs for localization and two CNNs for detection Santini 2017 [199] CNN coronary calcium detection using a seven layer CNN on image patches Lopez 2017 [200] CNN thrombus volume characterization using a 2D CNN and postprocessing Hong 2016 [201] DBN detection, segmentation, classification of abdominal aortic aneurysm using DBN and image patches Liu 2017 [202] CNN left atrium segmentation using a twelve layer CNN and active shape model (STA13) de Vos 2016 [203] CNN 3D localization of anatomical structures using three CNNs, one for each orthogonal plane Moradi 2016 [204] CNN detection of position for a given CT slice using a pretrained VGGnet, handcrafted features and SVM Zheng 2015 [205] Multiple carotid artery bifurcation detection using multi-layer perceptrons and probabilistic boosting-tree Montoya 2018 [206] ResNet 3D reconstruction of cerebral angiogram using a 30 layer ResNet Zreik 2018 [207] CNN, AE identify coronary artery stenosis using CNN for LV segmentation and an AE, SVM for classification Commandeur 2018 [208] CNN quantification of epicardial and thoracic adipose tissue from non-contrast CT Gulsun 2016 [209] CNN extract coronary centerline using optimal path from computed flow field and a CNN for refinement CNN carotid intima media thickness video interpretation using two CNNs with two layers on Ultrasound Tom 2017 [226] GAN IVUS image generation using two GANs (IV11) Wang 2017 [227] CNN breast arterial calcification using a ten layer CNN on mammograms Liu 2017 [228] CNN CAC detection using CNNs on 1768 X-Rays Pavoni 2017 [229] CNN denoising of percutaneous transluminal coronary angioplasty images using four layer CNN Nirschl 2018 [230] CNN trained a patch-based six layer CNN for identifying heart failure in endomyocardial biopsy images Betancur 2018 [231] CNN trained a three layer CNN for obstructive CAD prediction from myocardial perfusion imaging a Results from these imaging modalities are not reported in this review because they were highly variable in terms of the research question they were trying to solve and highly inconsistent in respect with the use of metrics. Additionally all papers use private databases besides…”

Section: Referencementioning

confidence: 99%

“…This model demonstrated better results than AlexNet, Inception and ResNet50. In [231] the authors trained a three layer CNN for the prediction of obstructive CAD stress myocardial perfusion from 1638 patients and compared it with total perfusion deficit. The model computes a probability per vessel during training, while in testing the maximum probabilities per artery are used per patient score.…”

Section: F Other Imaging Modalitiesmentioning

confidence: 99%

See 1 more Smart Citation

Deep Learning in Cardiology

Bizopoulos

Koutsouris

2019

IEEE Rev. Biomed. Eng.

130

View full text Add to dashboard Cite

The medical field is creating large amount of data that physicians are unable to decipher and use efficiently. Moreover, rule-based expert systems are inefficient in solving complicated medical tasks or for creating insights using big data. Deep learning has emerged as a more accurate and effective technology in a wide range of medical problems such as diagnosis, prediction and intervention. Deep learning is a representation learning method that consists of layers that transform the data non-linearly, thus, revealing hierarchical relationships and structures. In this review we survey deep learning application papers that use structured data, signal and imaging modalities from cardiology. We discuss the advantages and limitations of applying deep learning in cardiology that also apply in medicine in general, while proposing certain directions as the most viable for clinical use.

show abstract

“…There is a growing evidence, including large multicenter studies, that these solid-state SPECT systems demonstrate excellent diagnostic and prognostic utility in cardiac imaging. [6][7][8] In the last few years, the equipment companies have also introduced general-purpose CZT-based SPECT systems to enable applications other than cardiac imaging. These cameras benefit from improved energy and image resolution due to the CZT detectors and have demonstrated improved image quality in early clinical implementation as compared to general-purpose Angerbased systems.…”

mentioning

confidence: 99%

Do we need dedicated cardiac SPECT systems?

Slomka

2021

Journal of Nuclear Cardiology

View full text Add to dashboard Cite

Dedicated cardiac SPECT scanners have significantly improved in recent years, 1 reducing imaging time and radiation dose. In particular, cardiac scanners have entered clinical practice, 2,3 which use solid-state Cadmium-Zinc-Telluride (CZT) crystal detectors and feature innovative gantry designs, focusing on the heart. These new systems allow improvement in photon sensitivity (5-8 times higher) 4,5 for cardiac imaging, as well as image resolution (up to 2 times higher). 5 While solidstate CZT detectors are more expensive than traditional NaI(Tl) crystal detectors with photomultipliers, they do have important imaging advantages. The CZT detectors have improved energy response, which significantly reduces the scatter component of measured data. They also offer superior intrinsic spatial resolution compared to conventional Anger cameras. The use of less-bulky detectors (no need for photomultipliers) has resulted in more compact scanner size which has facilitated smallfootprint dedicated cardiac camera designs with custom imaging geometries and high-sensitivity collimation. There is a growing evidence, including large multicenter studies, that these solid-state SPECT systems demonstrate excellent diagnostic and prognostic utility in cardiac imaging. [6][7][8] In the last few years, the equipment companies have also introduced general-purpose CZT-based SPECT systems to enable applications other than cardiac imaging. These cameras benefit from improved energy and image resolution due to the CZT detectors and have demonstrated improved image quality in early clinical implementation as compared to general-purpose Angerbased systems. 9,10 GE has introduced general-purpose CZT-based cameras, the Discovery NM/CT 670 and 870, equipped with conventional collimators and CT attenuation correction. These cameras are not only designed for general-purpose imaging but also targeting cardiac imaging applications. The conventional collimator design of these cameras may avoid the difficulties in cardiac imaging, specific to the multipinhole collimation and small field-of-view on the dedicated cardiac cameras. 11 It is important, however, to point out that the general-purpose CZT cameras offer the same photon sensitivity as the conventional Anger systems, because the count sensitivity is related to the collimator and not the crystal. Thus, dedicated CZT cameras with specialized collimators can achieve much higher count sensitivity, consequently allowing faster acquisitions and lower injected doses. In particular, the 19-pinhole collimator, with each pinhole operating at a different focal depth, allows stationary image acquisition. Photons are acquired simultaneously through all the pinholes, allowing improved sensitivity as compared to the conventional camera with parallel collimators and rotating heads. For example, the reported measured system sensitivity of the Discovery NM/CT 670 CZT camera was 78 counts/s/MBq 12 compared to 460 counts/ s/MBq 5 for the dedicated GE 530 CZT design. Thus, in absolute terms, the sensitivity of the gen...

show abstract

Deep Learning for Prediction of Obstructive Disease From Fast Myocardial Perfusion SPECT

Abstract: Deep learning has the potential to improve automatic interpretation of MPI as compared with current clinical methods.

Cited by 262 publications

References 31 publications

Rationale and design of the REgistry of Fast Myocardial Perfusion Imaging with NExt generation SPECT (REFINE SPECT)

Rationale and design of the REgistry of Fast Myocardial Perfusion Imaging with NExt generation SPECT (REFINE SPECT)

Deep Learning in Cardiology

Do we need dedicated cardiac SPECT systems?

Contact Info

Product

Resources

About