Your search keyword '"Puyol A"' showing total 4 results

1. Deep Learning-Based Detection and Correction of Cardiac MR Motion Artefacts During Reconstruction for High-Quality Segmentation.

Author

Oksuz, Ilkay, Clough, James R., Ruijsink, Bram, Anton, Esther Puyol, Bustin, Aurelien, Cruz, Gastao, Prieto, Claudia, King, Andrew P., and Schnabel, Julia A.

Subjects

DEEP learning, COMPUTER-assisted image analysis (Medicine), K-spaces, IMAGE analysis, IMAGE reconstruction algorithms, IMAGE reconstruction, IMAGE segmentation

Abstract

Segmenting anatomical structures in medical images has been successfully addressed with deep learning methods for a range of applications. However, this success is heavily dependent on the quality of the image that is being segmented. A commonly neglected point in the medical image analysis community is the vast amount of clinical images that have severe image artefacts due to organ motion, movement of the patient and/or image acquisition related issues. In this paper, we discuss the implications of image motion artefacts on cardiac MR segmentation and compare a variety of approaches for jointly correcting for artefacts and segmenting the cardiac cavity. The method is based on our recently developed joint artefact detection and reconstruction method, which reconstructs high quality MR images from k-space using a joint loss function and essentially converts the artefact correction task to an under-sampled image reconstruction task by enforcing a data consistency term. In this paper, we propose to use a segmentation network coupled with this in an end-to-end framework. Our training optimises three different tasks: 1) image artefact detection, 2) artefact correction and 3) image segmentation. We train the reconstruction network to automatically correct for motion-related artefacts using synthetically corrupted cardiac MR k-space data and uncorrected reconstructed images. Using a test set of 500 2D+time cine MR acquisitions from the UK Biobank data set, we achieve demonstrably good image quality and high segmentation accuracy in the presence of synthetic motion artefacts. We showcase better performance compared to various image correction architectures. [ABSTRACT FROM AUTHOR]

Published

2020

2. Kiosk 4R-FA-04 - Associating Ai-derived Biomarkers of Systolic and Diastolic Biventricular Function with Mortality and Hospital Admissions.

Author

Jong, Marjan de, hersbach, Ferry, Puyol-Anton, Esther, Harana, Jorge Mariscal, King, Andrew, Razavi, Reza, Ofwegen, Clara van, and Ruijsink, Bram

Subjects

MORTALITY, PATIENTS, ARTIFICIAL intelligence, HOSPITAL admission & discharge, HOSPITAL care, HEART physiology, CONFERENCES & conventions, DIASTOLIC blood pressure, SYSTOLIC blood pressure, BIOMARKERS, HEART ventricles

Published

2024

3. Automated quantification of myocardial tissue characteristics from native T1 mapping using neural networks with uncertainty-based quality-control.

Author

Puyol-Antón, Esther, Ruijsink, Bram, Baumgartner, Christian F., Masci, Pier-Giorgio, Sinclair, Matthew, Konukoglu, Ender, Razavi, Reza, and King, Andrew P.

Subjects

*AUTOMATION, *CARDIOVASCULAR system, *CHEMICAL elements, *HEART, *ARTIFICIAL neural networks, *PROBABILITY theory, *QUALITY control, *TISSUES, *UNCERTAINTY, *RESEARCH bias, *MAGNETIC resonance angiography

Abstract

Background: Tissue characterisation with cardiovascular magnetic resonance (CMR) parametric mapping has the potential to detect and quantify both focal and diffuse alterations in myocardial structure not assessable by late gadolinium enhancement. Native T1 mapping in particular has shown promise as a useful biomarker to support diagnostic, therapeutic and prognostic decision-making in ischaemic and non-ischaemic cardiomyopathies. Methods: Convolutional neural networks (CNNs) with Bayesian inference are a category of artificial neural networks which model the uncertainty of the network output. This study presents an automated framework for tissue characterisation from native shortened modified Look-Locker inversion recovery ShMOLLI T1 mapping at 1.5 T using a Probabilistic Hierarchical Segmentation (PHiSeg) network (PHCUMIS 119–127, 2019). In addition, we use the uncertainty information provided by the PHiSeg network in a novel automated quality control (QC) step to identify uncertain T1 values. The PHiSeg network and QC were validated against manual analysis on a cohort of the UK Biobank containing healthy subjects and chronic cardiomyopathy patients (N=100 for the PHiSeg network and N=700 for the QC). We used the proposed method to obtain reference T1 ranges for the left ventricular (LV) myocardium in healthy subjects as well as common clinical cardiac conditions. Results: T1 values computed from automatic and manual segmentations were highly correlated (r=0.97). Bland-Altman analysis showed good agreement between the automated and manual measurements. The average Dice metric was 0.84 for the LV myocardium. The sensitivity of detection of erroneous outputs was 91%. Finally, T1 values were automatically derived from 11,882 CMR exams from the UK Biobank. For the healthy cohort, the mean (SD) corrected T1 values were 926.61 (45.26), 934.39 (43.25) and 927.56 (50.36) for global, interventricular septum and free-wall respectively. Conclusions: The proposed pipeline allows for automatic analysis of myocardial native T1 mapping and includes a QC process to detect potentially erroneous results. T1 reference values were presented for healthy subjects and common clinical cardiac conditions from the largest cohort to date using T1-mapping images. [ABSTRACT FROM AUTHOR]

Published

2020

4. Automatic CNN-based detection of cardiac MR motion artefacts using k-space data augmentation and curriculum learning.

Author

Oksuz, Ilkay, Ruijsink, Bram, Puyol-Antón, Esther, Clough, James R., Cruz, Gastao, Bustin, Aurelien, Prieto, Claudia, Botnar, Rene, Rueckert, Daniel, Schnabel, Julia A., and King, Andrew P.

Subjects

*DEEP learning, *MOTION, *RECEIVER operating characteristic curves, *MAGNETIC resonance, *IMAGE analysis, *ARTIFICIAL neural networks

Abstract

• An algorithm to automatically detect motion artefacts in cardiac MR short axis images. • Use of k-space corruption to generate realistic motion artefacts to address data imbalance. • Training of a spatio-temporal convolutional neural network using curriculum learning. • Detailed comparison against a range of machine learning methods. • An area under ROC curve of 0.89 is achieved. Good quality of medical images is a prerequisite for the success of subsequent image analysis pipelines. Quality assessment of medical images is therefore an essential activity and for large population studies such as the UK Biobank (UKBB), manual identification of artefacts such as those caused by unanticipated motion is tedious and time-consuming. Therefore, there is an urgent need for automatic image quality assessment techniques. In this paper, we propose a method to automatically detect the presence of motion-related artefacts in cardiac magnetic resonance (CMR) cine images. We compare two deep learning architectures to classify poor quality CMR images: 1) 3D spatio-temporal Convolutional Neural Networks (3D-CNN), 2) Long-term Recurrent Convolutional Network (LRCN). Though in real clinical setup motion artefacts are common, high-quality imaging of UKBB, which comprises cross-sectional population data of volunteers who do not necessarily have health problems creates a highly imbalanced classification problem. Due to the high number of good quality images compared to the relatively low number of images with motion artefacts, we propose a novel data augmentation scheme based on synthetic artefact creation in k-space. We also investigate a learning approach using a predetermined curriculum based on synthetic artefact severity. We evaluate our pipeline on a subset of the UK Biobank data set consisting of 3510 CMR images. The LRCN architecture outperformed the 3D-CNN architecture and was able to detect 2D+time short axis images with motion artefacts in less than 1ms with high recall. We compare our approach to a range of state-of-the-art quality assessment methods. The novel data augmentation and curriculum learning approaches both improved classification performance achieving overall area under the ROC curve of 0.89. [ABSTRACT FROM AUTHOR]

Published

2019