3D shape-based myocardial infarction prediction using point cloud classification networks
3D shape-based myocardial infarction prediction using point cloud classification networks
Myocardial infarction (MI) is one of the most prevalent cardiovascular diseases with associated clinical decision-making typically based on single-valued imaging biomarkers. However, such metrics only approximate the complex 3D structure and physiology of the heart and hence hinder a better understanding and prediction of MI outcomes. In this work, we investigate the utility of complete 3D cardiac shapes in the form of point clouds for an improved detection of MI events. To this end, we propose a fully automatic multi-step pipeline consisting of a 3D cardiac surface reconstruction step followed by a point cloud classification network. Our method utilizes recent advances in geometric deep learning on point clouds to enable direct and efficient multi-scale learning on high-resolution surface models of the cardiac anatomy. We evaluate our approach on 1068 UK Biobank subjects for the tasks of prevalent MI detection and incident MI prediction and find improvements of ∼13% and ∼5% respectively over clinical benchmarks. Furthermore, we analyze the role of each ventricle and cardiac phase for 3D shape-based MI detection and conduct a visual analysis of the morphological and physiological patterns typically associated with MI outcomes.Clinical relevance-The presented approach enables the fast and fully automatic pathology-specific analysis of full 3D cardiac shapes. It can thus be employed as a real-time diagnostic tool in clinical practice to discover and visualize more intricate biomarkers than currently used single-valued metrics and improve predictive accuracy of myocardial infarction.
3D Cardiac Shape Analysis, Cine MRI, Ejection Fraction, Geometric Deep Learning, Myocardial Infarction, Point Cloud Networks
Beetz, Marcel
8110d48b-e65e-408a-b126-6f63721dcc06
Yang, Yilong
a0d162d2-c118-40be-b724-d2e03bffc026
Banerjee, Abhirup
38c4aeb6-9b4d-48cc-bd6b-82137dfbd295
Li, Lei
2da88502-0bd8-4e6b-8f7d-0c01a48b399e
Grau, Vicente
c6992187-7840-45ce-93a0-d54d06031c7d
Beetz, Marcel
8110d48b-e65e-408a-b126-6f63721dcc06
Yang, Yilong
a0d162d2-c118-40be-b724-d2e03bffc026
Banerjee, Abhirup
38c4aeb6-9b4d-48cc-bd6b-82137dfbd295
Li, Lei
2da88502-0bd8-4e6b-8f7d-0c01a48b399e
Grau, Vicente
c6992187-7840-45ce-93a0-d54d06031c7d
Beetz, Marcel, Yang, Yilong and Banerjee, Abhirup
,
et al.
(2023)
3D shape-based myocardial infarction prediction using point cloud classification networks.
In 2023 45th Annual International Conference of the IEEE Engineering in Medicine and Biology Conference, EMBC 2023 - Proceedings.
IEEE.
4 pp
.
(doi:10.1109/EMBC40787.2023.10340878).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Myocardial infarction (MI) is one of the most prevalent cardiovascular diseases with associated clinical decision-making typically based on single-valued imaging biomarkers. However, such metrics only approximate the complex 3D structure and physiology of the heart and hence hinder a better understanding and prediction of MI outcomes. In this work, we investigate the utility of complete 3D cardiac shapes in the form of point clouds for an improved detection of MI events. To this end, we propose a fully automatic multi-step pipeline consisting of a 3D cardiac surface reconstruction step followed by a point cloud classification network. Our method utilizes recent advances in geometric deep learning on point clouds to enable direct and efficient multi-scale learning on high-resolution surface models of the cardiac anatomy. We evaluate our approach on 1068 UK Biobank subjects for the tasks of prevalent MI detection and incident MI prediction and find improvements of ∼13% and ∼5% respectively over clinical benchmarks. Furthermore, we analyze the role of each ventricle and cardiac phase for 3D shape-based MI detection and conduct a visual analysis of the morphological and physiological patterns typically associated with MI outcomes.Clinical relevance-The presented approach enables the fast and fully automatic pathology-specific analysis of full 3D cardiac shapes. It can thus be employed as a real-time diagnostic tool in clinical practice to discover and visualize more intricate biomarkers than currently used single-valued metrics and improve predictive accuracy of myocardial infarction.
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More information
e-pub ahead of print date: 11 December 2023
Venue - Dates:
45th Annual International Conference of the IEEE Engineering in Medicine and Biology Conference, EMBC 2023, , Sydney, Australia, 2023-07-24 - 2023-07-27
Keywords:
3D Cardiac Shape Analysis, Cine MRI, Ejection Fraction, Geometric Deep Learning, Myocardial Infarction, Point Cloud Networks
Identifiers
Local EPrints ID: 488775
URI: http://eprints.soton.ac.uk/id/eprint/488775
PURE UUID: ad633078-627a-4a66-8087-345ba566ea47
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Date deposited: 05 Apr 2024 16:38
Last modified: 10 Apr 2024 02:14
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Contributors
Author:
Marcel Beetz
Author:
Yilong Yang
Author:
Abhirup Banerjee
Author:
Lei Li
Author:
Vicente Grau
Corporate Author: et al.
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