Deep Learning Techniques for Automatic MRI Cardiac Multi-Structures Segmentation and Diagnosis: Is the Problem Solved?

Olivier Bernard , Alain Lalande , Clément Zotti , Olivier Bernard , Alain Lalande , Clément Zotti , Frederick Cervenansky , Xin Yang , Pheng‐Ann Heng , Irem Cetin , Karim Lekadir , Óscar Cámara , Miguel Á. González Ballester , Gerard Sanromà , Sandy Napel , Steffen E. Petersen , Georgios Tziritas , Elias Grinias , Mahendra Khened , Varghese Alex Kollerathu , Ganapathy Krishnamurthi , Marc-Michel Rohé , Xavier Pennec , Maxime Sermesant , Fabian Isensee , Paul F. Jäger , Klaus Maier‐Hein , Peter M. Full , Ivo Wolf , Sandy Engelhardt , Christian F. Baumgartner , Lisa M. Koch , Jelmer M. Wolterink , Ivana Išgum , Yeonggul Jang , Yoonmi Hong , Jay Patravali , Shubham Jain , Olivier Humbert , Pierre‐Marc Jodoin
2018 IEEE Transactions on Medical Imaging 1,933 citations

Abstract

Delineation of the left ventricular cavity, myocardium, and right ventricle from cardiac magnetic resonance images (multi-slice 2-D cine MRI) is a common clinical task to establish diagnosis. The automation of the corresponding tasks has thus been the subject of intense research over the past decades. In this paper, we introduce the "Automatic Cardiac Diagnosis Challenge" dataset (ACDC), the largest publicly available and fully annotated dataset for the purpose of cardiac MRI (CMR) assessment. The dataset contains data from 150 multi-equipments CMRI recordings with reference measurements and classification from two medical experts. The overarching objective of this paper is to measure how far state-of-the-art deep learning methods can go at assessing CMRI, i.e., segmenting the myocardium and the two ventricles as well as classifying pathologies. In the wake of the 2017 MICCAI-ACDC challenge, we report results from deep learning methods provided by nine research groups for the segmentation task and four groups for the classification task. Results show that the best methods faithfully reproduce the expert analysis, leading to a mean value of 0.97 correlation score for the automatic extraction of clinical indices and an accuracy of 0.96 for automatic diagnosis. These results clearly open the door to highly accurate and fully automatic analysis of cardiac CMRI. We also identify scenarios for which deep learning methods are still failing. Both the dataset and detailed results are publicly available online, while the platform will remain open for new submissions.

Keywords

Artificial intelligenceDeep learningComputer scienceSegmentationTask (project management)Machine learningFully automaticAutomationMedical imagingMagnetic resonance imagingPattern recognition (psychology)Image segmentationMedicineRadiology

MeSH Terms

Cardiac Imaging TechniquesDatabasesFactualDeep LearningFemaleHeartHeart DiseasesHumansImage InterpretationComputer-AssistedMagnetic Resonance ImagingMale

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Publication Info

Year
2018
Type
article
Volume
37
Issue
11
Pages
2514-2525
Citations
1933
Access
Closed

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Cite This

Olivier Bernard, Alain Lalande, Clément Zotti et al. (2018). Deep Learning Techniques for Automatic MRI Cardiac Multi-Structures Segmentation and Diagnosis: Is the Problem Solved?. IEEE Transactions on Medical Imaging , 37 (11) , 2514-2525. https://doi.org/10.1109/tmi.2018.2837502

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DOI
10.1109/tmi.2018.2837502
PMID
29994302

Data Quality

Data completeness: 86%