Literature DB >> 32090206

Fully Automated CT Quantification of Epicardial Adipose Tissue by Deep Learning: A Multicenter Study.

Frederic Commandeur1, Markus Goeller1, Aryabod Razipour1, Sebastien Cadet1, Michaela M Hell1, Jacek Kwiecinski1, Xi Chen1, Hyuk-Jae Chang1, Mohamed Marwan1, Stephan Achenbach1, Daniel S Berman1, Piotr J Slomka1, Balaji K Tamarappoo1, Damini Dey1.   

Abstract

PURPOSE: To evaluate the performance of deep learning for robust and fully automated quantification of epicardial adipose tissue (EAT) from multicenter cardiac CT data.
MATERIALS AND METHODS: In this multicenter study, a convolutional neural network approach was trained to quantify EAT on non-contrast material-enhanced calcium-scoring CT scans from multiple cohorts, scanners, and protocols (n = 850). Deep learning performance was compared with the performance of three expert readers and with interobserver variability in a subset of 141 scans. The deep learning algorithm was incorporated into research software. Automated EAT progression was compared with expert measurements for 70 patients with baseline and follow-up scans.
RESULTS: Automated quantification was performed in a mean (± standard deviation) time of 1.57 seconds ± 0.49, compared with 15 minutes for experts. Deep learning provided high agreement with expert manual quantification for all scans (R = 0.974; P < .001), with no significant bias (0.53 cm3; P = .13). Manual EAT volumes measured by two experienced readers were highly correlated (R = 0.984; P < .001) but with a bias of 4.35 cm3 (P < .001). Deep learning quantifications were highly correlated with the measurements of both experts (R = 0.973 and R = 0.979; P < .001), with significant bias for reader 1 (5.11 cm3; P < .001) but not for reader 2 (0.88 cm3; P = .26). EAT progression by deep learning correlated strongly with manual EAT progression (R = 0.905; P < .001) in 70 patients, with no significant bias (0.64 cm3; P = .43), and was related to an increased noncalcified plaque burden quantified from coronary CT angiography (5.7% vs 1.8%; P = .026).
CONCLUSION: Deep learning allows rapid, robust, and fully automated quantification of EAT from calcium scoring CT. It performs as well as an expert reader and can be implemented for routine cardiovascular risk assessment.© RSNA, 2019See also the commentary by Schoepf and Abadia in this issue. 2019 by the Radiological Society of North America, Inc.

Entities:  

Year:  2019        PMID: 32090206      PMCID: PMC6884062          DOI: 10.1148/ryai.2019190045

Source DB:  PubMed          Journal:  Radiol Artif Intell        ISSN: 2638-6100


  20 in total

1.  Increased pericardial fat volume measured from noncontrast CT predicts myocardial ischemia by SPECT.

Authors:  Balaji Tamarappoo; Damini Dey; Haim Shmilovich; Ryo Nakazato; Heidi Gransar; Victor Y Cheng; John D Friedman; Sean W Hayes; Louise E J Thomson; Piotr J Slomka; Alan Rozanski; Daniel S Berman
Journal:  JACC Cardiovasc Imaging       Date:  2010-11

2.  Automatic pericardium segmentation and quantification of epicardial fat from computed tomography angiography.

Authors:  Alexander Norlén; Jennifer Alvén; David Molnar; Olof Enqvist; Rauni Rossi Norrlund; John Brandberg; Göran Bergström; Fredrik Kahl
Journal:  J Med Imaging (Bellingham)       Date:  2016-09-15

3.  Pericardial fat burden on ECG-gated noncontrast CT in asymptomatic patients who subsequently experience adverse cardiovascular events.

Authors:  Victor Y Cheng; Damini Dey; Balaji Tamarappoo; Ryo Nakazato; Heidi Gransar; Romalisa Miranda-Peats; Amit Ramesh; Nathan D Wong; Leslee J Shaw; Piotr J Slomka; Daniel S Berman
Journal:  JACC Cardiovasc Imaging       Date:  2010-04

4.  Epicardial adipose tissue density and volume are related to subclinical atherosclerosis, inflammation and major adverse cardiac events in asymptomatic subjects.

Authors:  Markus Goeller; Stephan Achenbach; Mohamed Marwan; Mhairi K Doris; Sebastien Cadet; Frederic Commandeur; Xi Chen; Piotr J Slomka; Heidi Gransar; J Jane Cao; Nathan D Wong; Moritz H Albrecht; Alan Rozanski; Balaji K Tamarappoo; Daniel S Berman; Damini Dey
Journal:  J Cardiovasc Comput Tomogr       Date:  2017-11-24

5.  Relationship of epicardial fat volume to coronary plaque, severe coronary stenosis, and high-risk coronary plaque features assessed by coronary CT angiography.

Authors:  Ronak Rajani; Haim Shmilovich; Ryo Nakazato; Rine Nakanishi; Yuka Otaki; Victor Y Cheng; Sean W Hayes; Louise E J Thomson; John D Friedman; Piotr J Slomka; James K Min; Daniel S Berman; Damini Dey
Journal:  J Cardiovasc Comput Tomogr       Date:  2013-03-15

6.  Impact of coronary artery calcium scanning on coronary risk factors and downstream testing the EISNER (Early Identification of Subclinical Atherosclerosis by Noninvasive Imaging Research) prospective randomized trial.

Authors:  Alan Rozanski; Heidi Gransar; Leslee J Shaw; Johanna Kim; Lisa Miranda-Peats; Nathan D Wong; Jamal S Rana; Raza Orakzai; Sean W Hayes; John D Friedman; Louise E J Thomson; Donna Polk; James Min; Matthew J Budoff; Daniel S Berman
Journal:  J Am Coll Cardiol       Date:  2011-04-12       Impact factor: 24.094

7.  Association of epicardial adipose tissue and left atrial size on non-contrast CT with atrial fibrillation: the Heinz Nixdorf Recall Study.

Authors:  Amir A Mahabadi; Nils Lehmann; Hagen Kälsch; Marcus Bauer; Iryna Dykun; Kaffer Kara; Susanne Moebus; Karl-Heinz Jöckel; Raimund Erbel; Stefan Möhlenkamp
Journal:  Eur Heart J Cardiovasc Imaging       Date:  2014-02-04       Impact factor: 6.875

8.  Human epicardial adipose tissue is a source of inflammatory mediators.

Authors:  Tomasz Mazurek; LiFeng Zhang; Andrew Zalewski; John D Mannion; James T Diehl; Hwyda Arafat; Lea Sarov-Blat; Shawn O'Brien; Elizabeth A Keiper; Anthony G Johnson; Jack Martin; Barry J Goldstein; Yi Shi
Journal:  Circulation       Date:  2003-10-27       Impact factor: 29.690

9.  Epicardial Adipose Tissue Contributes to the Development of Non-Calcified Coronary Plaque: A 5-Year Computed Tomography Follow-up Study.

Authors:  In-Chang Hwang; Hyo Eun Park; Su-Yeon Choi
Journal:  J Atheroscler Thromb       Date:  2016-08-09       Impact factor: 4.928

10.  The coefficient of determination R2 and intra-class correlation coefficient from generalized linear mixed-effects models revisited and expanded.

Authors:  Shinichi Nakagawa; Paul C D Johnson; Holger Schielzeth
Journal:  J R Soc Interface       Date:  2017-09-13       Impact factor: 4.118
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  26 in total

1.  Machine learning to predict the long-term risk of myocardial infarction and cardiac death based on clinical risk, coronary calcium, and epicardial adipose tissue: a prospective study.

Authors:  Frederic Commandeur; Piotr J Slomka; Markus Goeller; Xi Chen; Sebastien Cadet; Aryabod Razipour; Priscilla McElhinney; Heidi Gransar; Stephanie Cantu; Robert J H Miller; Alan Rozanski; Stephan Achenbach; Balaji K Tamarappoo; Daniel S Berman; Damini Dey
Journal:  Cardiovasc Res       Date:  2020-12-01       Impact factor: 10.787

Review 2.  Artificial Intelligence in Cardiovascular Imaging for Risk Stratification in Coronary Artery Disease.

Authors:  Andrew Lin; Márton Kolossváry; Manish Motwani; Ivana Išgum; Pál Maurovich-Horvat; Piotr J Slomka; Damini Dey
Journal:  Radiol Cardiothorac Imaging       Date:  2021-02-25

Review 3.  Epicardial and pericardial fat analysis on CT images and artificial intelligence: a literature review.

Authors:  Federico Greco; Rodrigo Salgado; Wim Van Hecke; Romualdo Del Buono; Paul M Parizel; Carlo Augusto Mallio
Journal:  Quant Imaging Med Surg       Date:  2022-03

4.  Machine learning integration of circulating and imaging biomarkers for explainable patient-specific prediction of cardiac events: A prospective study.

Authors:  Balaji K Tamarappoo; Andrew Lin; Frederic Commandeur; Priscilla A McElhinney; Sebastien Cadet; Markus Goeller; Aryabod Razipour; Xi Chen; Heidi Gransar; Stephanie Cantu; Robert Jh Miller; Stephan Achenbach; John Friedman; Sean Hayes; Louise Thomson; Nathan D Wong; Alan Rozanski; Piotr J Slomka; Daniel S Berman; Damini Dey
Journal:  Atherosclerosis       Date:  2020-11-13       Impact factor: 5.162

5.  Greasing the Skids: Deep Learning for Fully Automated Quantification of Epicardial Fat.

Authors:  U Joseph Schoepf; Andres F Abadia
Journal:  Radiol Artif Intell       Date:  2019-11-27

Review 6.  Artificial intelligence in cardiovascular CT: Current status and future implications.

Authors:  Andrew Lin; Márton Kolossváry; Manish Motwani; Ivana Išgum; Pál Maurovich-Horvat; Piotr J Slomka; Damini Dey
Journal:  J Cardiovasc Comput Tomogr       Date:  2021-03-22

7.  Epicardial fat volume is associated with preexisting atrioventricular conduction abnormalities and increased pacemaker implantation rate in patients undergoing transcatheter aortic valve implantation.

Authors:  Maren Weferling; Andreas Rolf; Ulrich Fischer-Rasokat; Christoph Liebetrau; Matthias Renker; Yeoung-Hoon Choi; Christian W Hamm; Damini Dey; Won-Keun Kim
Journal:  Int J Cardiovasc Imaging       Date:  2021-12-26       Impact factor: 2.357

Review 8.  Artificial intelligence: improving the efficiency of cardiovascular imaging.

Authors:  Andrew Lin; Márton Kolossváry; Ivana Išgum; Pál Maurovich-Horvat; Piotr J Slomka; Damini Dey
Journal:  Expert Rev Med Devices       Date:  2020-06-16       Impact factor: 3.166

Review 9.  Application of artificial intelligence-driven endoscopic screening and diagnosis of gastric cancer.

Authors:  Yu-Jer Hsiao; Yuan-Chih Wen; Wei-Yi Lai; Yi-Ying Lin; Yi-Ping Yang; Yueh Chien; Aliaksandr A Yarmishyn; De-Kuang Hwang; Tai-Chi Lin; Yun-Chia Chang; Ting-Yi Lin; Kao-Jung Chang; Shih-Hwa Chiou; Ying-Chun Jheng
Journal:  World J Gastroenterol       Date:  2021-06-14       Impact factor: 5.742

10.  Automated Quality-Controlled Cardiovascular Magnetic Resonance Pericardial Fat Quantification Using a Convolutional Neural Network in the UK Biobank.

Authors:  Andrew Bard; Zahra Raisi-Estabragh; Maddalena Ardissino; Aaron Mark Lee; Francesca Pugliese; Damini Dey; Sandip Sarkar; Patricia B Munroe; Stefan Neubauer; Nicholas C Harvey; Steffen E Petersen
Journal:  Front Cardiovasc Med       Date:  2021-07-07
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