: Application

Application 11350

Title:	CARDIOMARKER- Computational imaging phenomics in population cardiac MRI with automatic image quality assessment: benchmarking, scalability and inference with state-of-the-art algorithms.
Lead Institution:	University of Manchester
Principal investigator:	Professor Alejandro Frangi

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About

Several cardiovascular conditions like heart failure, coronary artery disease, diabetes, and structural heart disease manifest in alterations of the anatomy or deformation of the myocardium. The hypothesis of this study is that existing tools for cardiac image analysis providing information on 3D cardiac morphology and deformation, developed for small patient cohorts, scale up to handle datasets in the order of hundreds and thousands of subjects. We will simultaneously undertake benchmarking of competing algorithms as demonstrate the impact of image analysis errors on relevant associative and causal inference tasks. CARDIOMARKER will carry out a large-scale scalability testing of current image analysis tools ultimately helping UK Biobank researchers in extracting objective imaging phenotypic biomarkers of cardiac morphology and deformation correlated to disease presence, severity or progression. We will manually assess a subset of the datasets by two operators in two independent sessions. We will compare the manually segmented cardiac structures (MR cine) and tag intersections (MR tagging) from manual analysis against those of our automatic techniques. CARDIOMARKER will elucidate how errors in CMR biomarkers influence the strength of associative and causal models. In collaboration with our clinical experts, we will formulate illustrative hypothesis re the association between cardiac morphology/deformation and genetic, lifestyle (activity, body mass composition), metabolism-related (bone ageing, liver function), environmental (exposures), and physiological (HR, BP) variables. We will generate associative/causative models, and will study the influence on those models of errors in CMR biomarkers derived from automatic analysis. This will shed light on the strength of the associations/causal relationships as a function of the size of the population and the noise level in the markers themselves. We want to answer these questions in relationship to manual delineation and previous performance of the techniques: a) What is the accuracy in cardiac anatomy delineation in population imaging studies? b) What is the accuracy of extracted cardiac deformation fields? c) What is the failure rate of automated methods operating on large-scale population imaging? d) What is the impact of automated segmentation/registration errors on associative/causative models of phenotype-genotype relationship? We will deliver the UKBB automatic and objective quantitative imaging information on the full cohort of patients imaged with CMR helping. These will establish population ranges of normality and thresholds of abnormality useful in cardiology. We will deliver knowledge on how to interpret and how errors compound in statistical modelling when attempting to unravel associative/causal relationships involving not only CMR but also other biomarkers.

1 Return

Return ID	App ID	Description	Archive Date
3126	11350	Quantitative CMR population imaging on 20,000 subjects of the UK Biobank imaging study: LV/RV quantification pipeline and its evaluation	5 Feb 2021

13 Publications

Pub ID	Title	Author(s)	Year	Journal
9697	A generalised deep meta-learning model for automated quality control of cardiovascular magnetic resonance images	Shahabedin Nabavi (+4)	2023	Computer Methods and Programs in Biomedicine
7124	Automatic 3D+t four-chamber CMR quantification of the UK biobank: integrating imaging and non-imaging data priors at scale	Yan Xia (+8)	2022	Medical Image Analysis
7454	Automatic segmentation of left and right ventricles in cardiac MRI using 3D-ASM and deep learning	Huaifei Hu (+6)	2021	Signal Processing Image Communication
13014	Compressed sensing using a deep adaptive perceptual generative adversarial network for MRI reconstruction from undersampled K-space data	Kun Wu (+3)	2024	Biomedical Signal Processing and Control
8081	DragNet: Learning-based deformable registration for realistic cardiac MR sequence generation from a single frame	Arezoo Zakeri (+8)	2022	Medical Image Analysis
10504	Fully Automatic initialization and segmentation of left and right ventricles for large-scale cardiac MRI using a deeply supervised network and 3D-ASM	Huaifei Hu (+2)	2023	Computer Methods and Programs in Biomedicine
12190	Joint shape/texture representation learning for cardiovascular disease diagnosis from magnetic resonance imaging	Xiang Chen (+4)	2024	European Heart Journal - Imaging Methods and Practice
12605	Learning to complete incomplete hearts for population analysis of cardiac MR images	Yan Xia (+2)	2022	Medical Image Analysis
3127	Quantitative CMR population imaging on 20,000 subjects of the UK Biobank imaging study: LV/RV quantification pipeline and its evaluation	Rahman Attar (+15)	2019	Medical Image Analysis
9239	Recovering from missing data in population imaging - Cardiac MR image imputation via conditional generative adversarial nets	Yan Xia (+7)	2020	Medical Image Analysis
10267	Shape registration with learned deformations for 3D shape reconstruction from sparse and incomplete point clouds	Xiang Chen (+8)	2021	Medical Image Analysis
7473	Super-Resolution of Cardiac MR Cine Imaging using Conditional GANs and Unsupervised Transfer Learning	Yan Xia (+5)	2021	Medical Image Analysis
10141	Unsupervised ensemble-based phenotyping enhances discoverability of genes related to left-ventricular morphology	Rodrigo Bonazzola (+7)	2024	Nature Machine Intelligence

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