AI-derived epicardial fat measurements improve cardiovascular risk prediction from myocardial perfusion imaging.
Robert J H MillerAakash ShanbhagAditya KillekarMark LemleyBryan P BednarskiSerge D Van KriekingePaul B KavanaghAttila FeherEdward J MillerAndrew J EinsteinTerrence D RuddyJoanna X LiangValerie BuiloffDaniel S BermanDamini DeyPiotr J SlomkaPublished in: NPJ digital medicine (2024)
Epicardial adipose tissue (EAT) volume and attenuation are associated with cardiovascular risk, but manual annotation is time-consuming. We evaluated whether automated deep learning-based EAT measurements from ungated computed tomography (CT) are associated with death or myocardial infarction (MI). We included 8781 patients from 4 sites without known coronary artery disease who underwent hybrid myocardial perfusion imaging. Of those, 500 patients from one site were used for model training and validation, with the remaining patients held out for testing (n = 3511 internal testing, n = 4770 external testing). We modified an existing deep learning model to first identify the cardiac silhouette, then automatically segment EAT based on attenuation thresholds. Deep learning EAT measurements were obtained in <2 s compared to 15 min for expert annotations. There was excellent agreement between EAT attenuation (Spearman correlation 0.90 internal, 0.82 external) and volume (Spearman correlation 0.90 internal, 0.91 external) by deep learning and expert segmentation in all 3 sites (Spearman correlation 0.90-0.98). During median follow-up of 2.7 years (IQR 1.6-4.9), 565 patients experienced death or MI. Elevated EAT volume and attenuation were independently associated with an increased risk of death or MI after adjustment for relevant confounders. Deep learning can automatically measure EAT volume and attenuation from low-dose, ungated CT with excellent correlation with expert annotations, but in a fraction of the time. EAT measurements offer additional prognostic insights within the context of hybrid perfusion imaging.
Keyphrases
- contrast enhanced
- computed tomography
- deep learning
- end stage renal disease
- adipose tissue
- ejection fraction
- dual energy
- low dose
- coronary artery disease
- newly diagnosed
- chronic kidney disease
- artificial intelligence
- machine learning
- high resolution
- convolutional neural network
- type diabetes
- heart failure
- left ventricular
- metabolic syndrome
- insulin resistance
- image quality
- atrial fibrillation
- high fat diet
- aortic stenosis
- clinical practice
- skeletal muscle
- coronary artery bypass grafting