Cardiac Gating Methods for Coronary Magnetic Resonance Angiography

Liu, Garry

22 July 2014

Coronary magnetic resonance angiography (CMRA) is a potential diagnostic tool for coronary artery disease (CAD). Compared to the current gold standard, x-ray angiography, CMRA provides three-dimensional visualization of coronary vessel lumens without the use of catheters and ionizing radiation. CMRA, however, requires long acquisition times that span multiple heartbeats. Typically, to reduce cardiac motion artifacts, electrocardiogram (ECG) gating is used to synchronize data acquisition windows to diastasis periods. Gating errors may cause vessel blurring by unintentionally triggering the scanner to acquire image data during periods of significant cardiac motion. This is particularly problematic for CMRA because of the associated fine spatial resolution requirement for diagnosing CAD. This thesis presents and tests the novel idea of determining the timing of global epicardial diastasis periods from the motion of the basal ventricular septum. An experiment involving a small patient cohort undergoing elective diagnostic angiography revealed a significant correlation between the beat-to-beat diastasis periods of the ventricular septum and the coronary vasculature. This motivated the ii development and testing of the hypothesis that suggests sharper coronary artery images may be obtained by using cardiac gating windows determined by septal motion. A preliminary study involving a small volunteer cohort provided encouraging results, but also revealed limitations of using ultrasound to measure septal motion during a pre- scan prior to an MRA exam. This led to the major technical development of this thesis, which is a magnetic resonance imaging (MRI) method called the Septal Scout for monitoring septal motion at a very high temporal resolution. The technique was applied to a volunteer cohort which showed that cardiac gating windows as determined by the Septal Scout provided sharper coronary images compared with conventional ECG gating. The scientific knowledge and technical developments presented in this thesis are intended to improve CMRA as a non-invasive diagnostic tool of CAD. In the future, I intend to integrate the concepts presented here into a functioning MRI-based cardiac gating system. As well, I intend to validate the Septal Scout in a patient cohort study.

Magnetic Resonance Imaging

Coronary Angiography

Cardiac Gating

Coronary Artery Disease

0760

Adaptation des paramètres temporels en imagerie par résonance magnétique en fonction des variations physiologiques du rythme cardiaque. Application à la cartograhie T2 / Temporal parameters adaptation in Magnetic Resonance Imaging according to physiological Heart Rate variations. Application to T2 mapping

Soumoy de Roquefeuil, Marion

07 June 2013

L'imagerie par Résonance Magnétique (IRM) cardiaque est un domaine qui nécessite d'adapter la séquence au rythme du coeur, afin d'éviter le flou causé par un temps d'acquisition long devant les constantes de temps du mouvement. Ainsi, les temps séparant les impulsions radio-fréquence (RF) de la séquence sont aussi variables que les durées des cycles cardiaques sur lesquels on synchronise l'acquisition. Cela est cause d'imprécision sur l'image résultante, en particulier dans son caractère quantitatif. L'aimantation des spins n'est effectivement pas dans un état d'équilibre sur toute l'acquisition. La thèse présente deux axes principaux de recherche explorés ; le premier est une étude de l'impact de la variation du rythme cardiaque (présentée en outre dans le manuscrit) sur la mesure quantitative du temps de relaxation transversal T2. L'étude a été menée sur des objets fantômes et sur des volontaires sains. Deux méthodes de correction de la variation du rythme sont proposées, l'une basée sur la correction du signal au centre de l'espace de Fourier, l'autre basée sur une approche de reconstruction généralisée. Les résultats préliminaires sont encourageants, et des travaux ultérieurs seraient à entreprendre pour confirmer l'efficacité de ces méthodes. Ensuite, les variations temporelles du cycle cardiaque sont traitées à l'échelle d'un cycle, et nous proposons une méthode de mise en coïncidence des différents segments de l'électrocardiogramme (ECG) basée sur la déformation de l'ECG dans l'IRM probablement par effet magnétohydrodynamique. Cette méthode est mise au service de l'imagerie dans le cadre d'une séquence cinétique CINE dans laquelle une meilleure mise en correspondance des segments de cycles cardiaques successifs devrait permettre de gagner en qualité d'image, à condition d'avoir des résolutions spatiale et temporelle suffisamment fines. Les résultats apportés au cours de cette thèse sont préliminaires à de futures recherches nécessaires dans le domaine temporel de la séquence, beaucoup moins traité que le mouvement des organes / Cardiac Magnetic Resonance Imaging (MRI) requires to adapt the sequence to heart rate, so as to avoid the blur caused by the acquisition time longer than motion time constants. Thus, times between sequence radiofrequency pulses are as much variable as synchronization cardiac cycles durations. It causes imprecision on the resulting image, particularly for quantification. In fact, spins magnetization is not in a steady state during the acquisition. Two main research axis are presented in this thesis; the first one is a study of the impact of heart rate variation (described in the manuscript) on the transversal relaxation time T2 quantitative measurement. The study was lead on both phantom objects and on healthy volunteers. Two correction methods for heart rate variation are proposed, one based on the correction of the signal of the central line of the k-space, the other one based on a generalized reconstruction approach. First results are encouraging, and further works should be lead to confirm the methods efficacity. Then, heart rate variations are treated inside the cardiac cycle, and we propose a method to match the different segments of the electrocardiogram (ECG), based on the ECG deformation in the MR scanner probably due to by magnetohydrodynamic effect. This method is applied on imaging with a CINE kinetic sequence in which a better successive cardiac cycles segments matching should enable to improve image quality, at the condition to have sharp enough spatial and temporal resolutions. Results brought in this thesis are preliminary to necessary future researches in the sequence time domain, largely less addressed than organ motion

IRM cardiaque

IRM adaptative

IRM quantitative

T2

Variation du rythme cardiaque

ECG

Synchronisation cardiaque

Reconstruction généralisée

Normalisation multi-linéaire

Cardiac MRI

Adaptive MRI

Quantitative MRI

T2

Heart rate variation

ECG

Cardiac gating

Generalized reconstruction

Multilinear stretching

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