Modeling 3D cardiac contraction and relaxation with point cloud deformation networks

TL;DR

This paper introduces PCD-Net, a deep learning model that accurately captures 3D cardiac deformation from point cloud data, outperforming clinical benchmarks in MI detection and prediction.

Contribution

The novel PCD-Net leverages point cloud deep learning for detailed 3D cardiac modeling, enabling better clinical insights and predictive performance.

Findings

Average Chamfer distance below image pixel resolution.

Similar clinical metrics between predicted and actual data.

Outperforms benchmarks in MI detection and prediction by 13% and 7%.

Abstract

Global single-valued biomarkers of cardiac function typically used in clinical practice, such as ejection fraction, provide limited insight on the true 3D cardiac deformation process and hence, limit the understanding of both healthy and pathological cardiac mechanics. In this work, we propose the Point Cloud Deformation Network (PCD-Net) as a novel geometric deep learning approach to model 3D cardiac contraction and relaxation between the extreme ends of the cardiac cycle. It employs the recent advances in point cloud-based deep learning into an encoder-decoder structure, in order to enable efficient multi-scale feature learning directly on multi-class 3D point cloud representations of the cardiac anatomy. We evaluate our approach on a large dataset of over 10,000 cases from the UK Biobank study and find average Chamfer distances between the predicted and ground truth anatomies below the pixel resolution of the underlying image acquisition. Furthermore, we observe similar clinical metrics between predicted and ground truth populations and show that the PCD-Net can successfully capture subpopulation-specific differences between normal subjects and myocardial infarction (MI) patients. We then demonstrate that the learned 3D deformation patterns outperform multiple clinical benchmarks by 13% and 7% in terms of area under the receiver operating characteristic curve for the tasks of prevalent MI detection and incident MI prediction and by 7% in terms of Harrell's concordance index for MI survival analysis.