machine-learning

To develop and evaluate a deep learning model that can be combined with parallel imaging or compressed sensing (CS).

To develop and evaluate a free-breathing and electrocardiogram-free real-time cine with deep learning-based radial acceleration for Ex-CMR.

To improve the accuracy and robustness of T1 estimation by MyoMapNet, a deep learning–based approach using 4 inversion‐recovery T1‐weighted images for cardiac T1 mapping.

The objective of the current study was to investigate the performance of various deep learning architectures for MyoMapNet, a DL model for T1 estimation using accelerated cardiac T1 mapping from four T1‐weighted images collected after a single inversion pulse.

We implemented an explainable machine learning (ML) model to gain insight into the association between cardiovascular MR (CMR) imaging markers and adverse outcomes of cardiovascular (CV) hospitalization and all-cause death (composite endpoint) in patients with non-ischemic dilated cardiomyopathy (NICM).

To develop and evaluate MyoMapNet, a rapid myocardial T1 mapping approach that uses fully connected neural networks (FCNN) to estimate T1 values from four T1-weighted images collected after a single inversion pulse in four heartbeats (Look-Locker, LL4).