Deep‐Learning‐Based Disease Classification in Patients Undergoing Cine Cardiac MRI

Background Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI. Purpose To develop an MRI‐based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hyper...

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Published in	Journal of magnetic resonance imaging Vol. 61; no. 4; pp. 1635 - 1647
Main Authors	Jacob, Athira J., Chitiboi, Teodora, Schoepf, U. Joseph, Sharma, Puneet, Aldinger, Jonathan, Baker, Charles, Lautenschlager, Carla, Emrich, Tilman, Varga‐Szemes, Akos
Format	Journal Article
Language	English
Published	Hoboken, USA John Wiley & Sons, Inc 01.04.2025 Wiley Subscription Services, Inc
Subjects	Accuracy Adult Aged Algorithms Cardiomyopathy Cardiomyopathy, Dilated - diagnostic imaging Cardiomyopathy, Hypertrophic - diagnostic imaging Cardiovascular diseases Classification Confidence intervals Deep Learning Dilated cardiomyopathy Disease disease classification Feature extraction Female Field strength Heart - diagnostic imaging Heart diseases Heart Ventricles - diagnostic imaging Humans Image Interpretation, Computer-Assisted - methods Image Processing, Computer-Assisted - methods Ischemia Labels Machine learning Magnetic resonance imaging Magnetic Resonance Imaging, Cine - methods Male Middle Aged model interpretability Myocardial Ischemia - diagnostic imaging myocardial strain Population studies Reproducibility of Results Retrospective Studies Sensitivity and Specificity Statistical analysis Statistical tests Ventricle deep learning myocardial strain model interpretability disease classification
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Abstract	Background Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI. Purpose To develop an MRI‐based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hypertrophic cardiomyopathy (HCM), and ischemic heart disease (IHD). Study Type Retrospective. Population A total of 1337 subjects (55% female), comprising normal subjects (N = 568), and patients with DCM (N = 151), HCM (N = 177), and IHD (N = 441). Field Strength/Sequence Balanced steady‐state free precession cine sequence at 1.5/3.0 T. Assessment Bi‐ventricular morphological and functional features and global and segmental left ventricular strain features were automatically extracted from short‐ and long‐axis cine images. Variational autoencoder models were trained on the extracted features and compared against consensus disease label provided by two expert readers (13 and 14 years of experience). Adding unlabeled, normal data to the training was explored to increase specificity of NORM class. Statistical Tests Tenfold cross‐validation for model development; mean, standard deviation (SD) for measurements; classification metrics: area under the curve (AUC), confusion matrix, accuracy, specificity, precision, recall; 95% confidence intervals; Mann–Whitney U test for significance. Results AUCs of 0.952 for NORM, 0.881 for DCM, 0.908 for HCM, and 0.856 for IHD and overall accuracy of 0.778 were obtained, with specificity of 0.908 for the NORM class using both SAX and LAX features. Longitudinal strain features slightly improved classification metrics by 0.001 to 0.03 points, except for HCM‐AUC. Differences in accuracy, metrics for NORM class and HCM‐AUC were statistically significant. Cotraining using unlabeled data increased the specificity for the NORM class to 0.961. Data Conclusion Cardiac function features automatically extracted from cine MRI have potential to be used for disease classification, especially for normal‐abnormal classification. Feature analyses showed that strain features were important for disease labeling. Cotraining using unlabeled data may help to increase specificity for normal‐abnormal classification. Level of Evidence 3 Technical Efficacy Stage 1
AbstractList	Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI. To develop an MRI-based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hypertrophic cardiomyopathy (HCM), and ischemic heart disease (IHD). Retrospective. A total of 1337 subjects (55% female), comprising normal subjects (N = 568), and patients with DCM (N = 151), HCM (N = 177), and IHD (N = 441). Balanced steady-state free precession cine sequence at 1.5/3.0 T. Bi-ventricular morphological and functional features and global and segmental left ventricular strain features were automatically extracted from short- and long-axis cine images. Variational autoencoder models were trained on the extracted features and compared against consensus disease label provided by two expert readers (13 and 14 years of experience). Adding unlabeled, normal data to the training was explored to increase specificity of NORM class. Tenfold cross-validation for model development; mean, standard deviation (SD) for measurements; classification metrics: area under the curve (AUC), confusion matrix, accuracy, specificity, precision, recall; 95% confidence intervals; Mann-Whitney U test for significance. AUCs of 0.952 for NORM, 0.881 for DCM, 0.908 for HCM, and 0.856 for IHD and overall accuracy of 0.778 were obtained, with specificity of 0.908 for the NORM class using both SAX and LAX features. Longitudinal strain features slightly improved classification metrics by 0.001 to 0.03 points, except for HCM-AUC. Differences in accuracy, metrics for NORM class and HCM-AUC were statistically significant. Cotraining using unlabeled data increased the specificity for the NORM class to 0.961. Cardiac function features automatically extracted from cine MRI have potential to be used for disease classification, especially for normal-abnormal classification. Feature analyses showed that strain features were important for disease labeling. Cotraining using unlabeled data may help to increase specificity for normal-abnormal classification. 3 TECHNICAL EFFICACY: Stage 1. BackgroundAutomated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI.PurposeTo develop an MRI‐based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hypertrophic cardiomyopathy (HCM), and ischemic heart disease (IHD).Study TypeRetrospective.PopulationA total of 1337 subjects (55% female), comprising normal subjects (N = 568), and patients with DCM (N = 151), HCM (N = 177), and IHD (N = 441).Field Strength/SequenceBalanced steady‐state free precession cine sequence at 1.5/3.0 T.AssessmentBi‐ventricular morphological and functional features and global and segmental left ventricular strain features were automatically extracted from short‐ and long‐axis cine images. Variational autoencoder models were trained on the extracted features and compared against consensus disease label provided by two expert readers (13 and 14 years of experience). Adding unlabeled, normal data to the training was explored to increase specificity of NORM class.Statistical TestsTenfold cross‐validation for model development; mean, standard deviation (SD) for measurements; classification metrics: area under the curve (AUC), confusion matrix, accuracy, specificity, precision, recall; 95% confidence intervals; Mann–Whitney U test for significance.ResultsAUCs of 0.952 for NORM, 0.881 for DCM, 0.908 for HCM, and 0.856 for IHD and overall accuracy of 0.778 were obtained, with specificity of 0.908 for the NORM class using both SAX and LAX features. Longitudinal strain features slightly improved classification metrics by 0.001 to 0.03 points, except for HCM‐AUC. Differences in accuracy, metrics for NORM class and HCM‐AUC were statistically significant. Cotraining using unlabeled data increased the specificity for the NORM class to 0.961.Data ConclusionCardiac function features automatically extracted from cine MRI have potential to be used for disease classification, especially for normal‐abnormal classification. Feature analyses showed that strain features were important for disease labeling. Cotraining using unlabeled data may help to increase specificity for normal‐abnormal classification.Level of Evidence3Technical EfficacyStage 1 Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI.BACKGROUNDAutomated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI.To develop an MRI-based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hypertrophic cardiomyopathy (HCM), and ischemic heart disease (IHD).PURPOSETo develop an MRI-based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hypertrophic cardiomyopathy (HCM), and ischemic heart disease (IHD).Retrospective.STUDY TYPERetrospective.A total of 1337 subjects (55% female), comprising normal subjects (N = 568), and patients with DCM (N = 151), HCM (N = 177), and IHD (N = 441).POPULATIONA total of 1337 subjects (55% female), comprising normal subjects (N = 568), and patients with DCM (N = 151), HCM (N = 177), and IHD (N = 441).Balanced steady-state free precession cine sequence at 1.5/3.0 T.FIELD STRENGTH/SEQUENCEBalanced steady-state free precession cine sequence at 1.5/3.0 T.Bi-ventricular morphological and functional features and global and segmental left ventricular strain features were automatically extracted from short- and long-axis cine images. Variational autoencoder models were trained on the extracted features and compared against consensus disease label provided by two expert readers (13 and 14 years of experience). Adding unlabeled, normal data to the training was explored to increase specificity of NORM class.ASSESSMENTBi-ventricular morphological and functional features and global and segmental left ventricular strain features were automatically extracted from short- and long-axis cine images. Variational autoencoder models were trained on the extracted features and compared against consensus disease label provided by two expert readers (13 and 14 years of experience). Adding unlabeled, normal data to the training was explored to increase specificity of NORM class.Tenfold cross-validation for model development; mean, standard deviation (SD) for measurements; classification metrics: area under the curve (AUC), confusion matrix, accuracy, specificity, precision, recall; 95% confidence intervals; Mann-Whitney U test for significance.STATISTICAL TESTSTenfold cross-validation for model development; mean, standard deviation (SD) for measurements; classification metrics: area under the curve (AUC), confusion matrix, accuracy, specificity, precision, recall; 95% confidence intervals; Mann-Whitney U test for significance.AUCs of 0.952 for NORM, 0.881 for DCM, 0.908 for HCM, and 0.856 for IHD and overall accuracy of 0.778 were obtained, with specificity of 0.908 for the NORM class using both SAX and LAX features. Longitudinal strain features slightly improved classification metrics by 0.001 to 0.03 points, except for HCM-AUC. Differences in accuracy, metrics for NORM class and HCM-AUC were statistically significant. Cotraining using unlabeled data increased the specificity for the NORM class to 0.961.RESULTSAUCs of 0.952 for NORM, 0.881 for DCM, 0.908 for HCM, and 0.856 for IHD and overall accuracy of 0.778 were obtained, with specificity of 0.908 for the NORM class using both SAX and LAX features. Longitudinal strain features slightly improved classification metrics by 0.001 to 0.03 points, except for HCM-AUC. Differences in accuracy, metrics for NORM class and HCM-AUC were statistically significant. Cotraining using unlabeled data increased the specificity for the NORM class to 0.961.Cardiac function features automatically extracted from cine MRI have potential to be used for disease classification, especially for normal-abnormal classification. Feature analyses showed that strain features were important for disease labeling. Cotraining using unlabeled data may help to increase specificity for normal-abnormal classification.DATA CONCLUSIONCardiac function features automatically extracted from cine MRI have potential to be used for disease classification, especially for normal-abnormal classification. Feature analyses showed that strain features were important for disease labeling. Cotraining using unlabeled data may help to increase specificity for normal-abnormal classification.3 TECHNICAL EFFICACY: Stage 1.LEVEL OF EVIDENCE3 TECHNICAL EFFICACY: Stage 1. Background Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI. Purpose To develop an MRI‐based deep learning (DL) disease classification algorithm to distinguish among normal subjects (NORM), patients with dilated cardiomyopathy (DCM), hypertrophic cardiomyopathy (HCM), and ischemic heart disease (IHD). Study Type Retrospective. Population A total of 1337 subjects (55% female), comprising normal subjects (N = 568), and patients with DCM (N = 151), HCM (N = 177), and IHD (N = 441). Field Strength/Sequence Balanced steady‐state free precession cine sequence at 1.5/3.0 T. Assessment Bi‐ventricular morphological and functional features and global and segmental left ventricular strain features were automatically extracted from short‐ and long‐axis cine images. Variational autoencoder models were trained on the extracted features and compared against consensus disease label provided by two expert readers (13 and 14 years of experience). Adding unlabeled, normal data to the training was explored to increase specificity of NORM class. Statistical Tests Tenfold cross‐validation for model development; mean, standard deviation (SD) for measurements; classification metrics: area under the curve (AUC), confusion matrix, accuracy, specificity, precision, recall; 95% confidence intervals; Mann–Whitney U test for significance. Results AUCs of 0.952 for NORM, 0.881 for DCM, 0.908 for HCM, and 0.856 for IHD and overall accuracy of 0.778 were obtained, with specificity of 0.908 for the NORM class using both SAX and LAX features. Longitudinal strain features slightly improved classification metrics by 0.001 to 0.03 points, except for HCM‐AUC. Differences in accuracy, metrics for NORM class and HCM‐AUC were statistically significant. Cotraining using unlabeled data increased the specificity for the NORM class to 0.961. Data Conclusion Cardiac function features automatically extracted from cine MRI have potential to be used for disease classification, especially for normal‐abnormal classification. Feature analyses showed that strain features were important for disease labeling. Cotraining using unlabeled data may help to increase specificity for normal‐abnormal classification. Level of Evidence 3 Technical Efficacy Stage 1
Author	Emrich, Tilman Chitiboi, Teodora Baker, Charles Schoepf, U. Joseph Sharma, Puneet Aldinger, Jonathan Lautenschlager, Carla Varga‐Szemes, Akos Jacob, Athira J.
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Snippet	Background Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI. Purpose To develop an MRI‐based deep... Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI. To develop an MRI-based deep learning (DL)... BackgroundAutomated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI.PurposeTo develop an MRI‐based deep... Automated approaches may allow for fast, reproducible clinical assessment of cardiovascular diseases from MRI.BACKGROUNDAutomated approaches may allow for...
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SubjectTerms	Accuracy Adult Aged Algorithms Cardiomyopathy Cardiomyopathy, Dilated - diagnostic imaging Cardiomyopathy, Hypertrophic - diagnostic imaging Cardiovascular diseases Classification Confidence intervals Deep Learning Dilated cardiomyopathy Disease disease classification Feature extraction Female Field strength Heart - diagnostic imaging Heart diseases Heart Ventricles - diagnostic imaging Humans Image Interpretation, Computer-Assisted - methods Image Processing, Computer-Assisted - methods Ischemia Labels Machine learning Magnetic resonance imaging Magnetic Resonance Imaging, Cine - methods Male Middle Aged model interpretability Myocardial Ischemia - diagnostic imaging myocardial strain Population studies Reproducibility of Results Retrospective Studies Sensitivity and Specificity Statistical analysis Statistical tests Ventricle
Title	Deep‐Learning‐Based Disease Classification in Patients Undergoing Cine Cardiac MRI
URI	https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fjmri.29619 https://www.ncbi.nlm.nih.gov/pubmed/39353848 https://www.proquest.com/docview/3176111824 https://www.proquest.com/docview/3112525490
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