Your search keyword '"Allain, Pascal"' showing total 2 results

1. Cardiac Electrophysiological Activation Pattern Estimation From Images Using a Patient-Specific Database of Synthetic Image Sequences.

Author

Prakosa, Adityo, Sermesant, Maxime, Allain, Pascal, Villain, Nicolas, Rinaldi, C. Aldo, Rhode, Kawal, Razavi, Reza, Delingette, Herve, and Ayache, Nicholas

Subjects

CARDIOVASCULAR diseases, ELECTROPHYSIOLOGY, COMPUTER simulation, INVERSE problems, MACHINE learning, ELECTRIC properties of hearts

Abstract

While abnormal patterns of cardiac electrophysiological activation are at the origin of important cardiovascular diseases (e.g., arrhythmia, asynchrony), the only clinically available method to observe detailed left ventricular endocardial surface activation pattern is through invasive catheter mapping. However, this electrophysiological activation controls the onset of the mechanical contraction; therefore, important information about the electrophysiology could be deduced from the detailed observation of the resulting motion patterns. In this paper, we present the study of this inverse cardiac electrokinematic relationship. The objective is to predict the activation pattern knowing the cardiac motion from the analysis of cardiac image sequences. To achieve this, we propose to create a rich patient-specific database of synthetic time series of the cardiac images using simulations of a personalized cardiac electromechanical model, in order to study this complex relationship between electrical activity and kinematic patterns in the context of this specific patient. We use this database to train a machine-learning algorithm which estimates the depolarization times of each cardiac segment from global and regional kinematic descriptors based on displacements or strains and their derivatives. Finally, we use this learning to estimate the patient’s electrical activation times using the acquired clinical images. Experiments on the inverse electrokinematic learning are demonstrated on synthetic sequences and are evaluated on clinical data with promising results. The error calculated between our prediction and the invasive intracardiac mapping ground truth is relatively small (around 10 ms for ischemic patients and 20 ms for nonischemic patient). This approach suggests the possibility of noninvasive electrophysiological pattern estimation using cardiac motion imaging. [ABSTRACT FROM PUBLISHER]

Published

2014

2. Generation of Synthetic but Visually Realistic Time Series of Cardiac Images Combining a Biophysical Model and Clinical Images.

Author

Prakosa, Adityo, Sermesant, Maxime, Delingette, Hervé, Marchesseau, Stéphanie, Saloux, Eric, Allain, Pascal, Villain, Nicolas, and Ayache, Nicholas

Subjects

CARDIAC imaging, TIME series analysis, MEDICAL imaging systems, ELECTROMECHANICAL technology, FOUR-dimensional imaging, BIOLOGICAL systems, CARDIOMYOPATHIES

Abstract

We propose a new approach for the generation of synthetic but visually realistic time series of cardiac images based on an electromechanical model of the heart and real clinical 4-D image sequences. This is achieved by combining three steps. The first step is the simulation of a cardiac motion using an electromechanical model of the heart and the segmentation of the end diastolic image of a cardiac sequence. We use biophysical parameters related to the desired condition of the simulated subject. The second step extracts the cardiac motion from the real sequence using nonrigid image registration. Finally, a synthetic time series of cardiac images corresponding to the simulated motion is generated in the third step by combining the motion estimated by image registration and the simulated one. With this approach, image processing algorithms can be evaluated as we know the ground-truth motion underlying the image sequence. Moreover, databases of visually realistic images of controls and patients can be generated for which the underlying cardiac motion and some biophysical parameters are known. Such databases can open new avenues for machine learning approaches. [ABSTRACT FROM PUBLISHER]

Published

2013