2008 - Fellow of the Indian National Academy of Engineering (INAE)
Elliot R. McVeigh mainly investigates Magnetic resonance imaging, Nuclear medicine, Biomedical engineering, Internal medicine and Cardiology. Magnetic resonance imaging is the subject of his research, which falls under Radiology. His biological study spans a wide range of topics, including Image quality, Real-time MRI and Cine mri.
His Biomedical engineering research is multidisciplinary, relying on both Mri guided, Antenna and Reference values. He combines subjects such as Endocardium, Electrocardiography, Left bundle branch block and Planar Imaging with his study of Systole. His Ventricle research incorporates elements of Fiber, Anisotropy, Nuclear magnetic resonance and Heart septum.
His primary areas of investigation include Magnetic resonance imaging, Artificial intelligence, Biomedical engineering, Computer vision and Internal medicine. His Magnetic resonance imaging research includes themes of Ventricle, Myocardial infarction, Nuclear medicine and Nuclear magnetic resonance. His study in Nuclear magnetic resonance is interdisciplinary in nature, drawing from both Imaging phantom, Optics, Steady state, Cardiac imaging and Signal.
The various areas that he examines in his Biomedical engineering study include Diffusion MRI, Simulation and Ablation. In his work, Image resolution is strongly intertwined with Temporal resolution, which is a subfield of Computer vision. His Internal medicine research focuses on Cardiology and how it relates to Systole and Diastole.
Elliot R. McVeigh spends much of his time researching Internal medicine, Cardiology, Biomedical engineering, Nuclear medicine and Patient specific. The Mitral valve, Diastole and Cohort research Elliot R. McVeigh does as part of his general Internal medicine study is frequently linked to other disciplines of science, such as Blood stasis and In patient, therefore creating a link between diverse domains of science. His Biomedical engineering study integrates concerns from other disciplines, such as Image resolution, Imaging phantom, Cardiac imaging and Cardiac cycle.
His work deals with themes such as Pet mr imaging, Mri guided, Motion correction and Computed tomography, which intersect with Nuclear medicine. His study looks at the relationship between Image quality and topics such as Pulse sequence, which overlap with Magnetic resonance imaging. His Magnetic resonance imaging research incorporates themes from Tissue thickness, Pulse and Varying thickness.
His scientific interests lie mostly in Internal medicine, Cardiology, Myocardial infarction, Human heart and Diffusion MRI. His primary area of study in Internal medicine is in the field of Coronary artery calcium. He integrates Cardiology with In patient in his study.
His work carried out in the field of Myocardial infarction brings together such families of science as Cardiac function curve, Nuclear medicine, Confidence interval, Cardiac imaging and Magnetic resonance imaging. His Magnetic resonance imaging study combines topics from a wide range of disciplines, such as Ex vivo, Geometry, Binary image and Ischemic cardiomyopathy. His Diffusion MRI research integrates issues from Anatomy, Atrial anatomy, Nuclear magnetic resonance and Atrial wall.
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Mapping of regional myocardial strain and work during ventricular pacing: experimental study using magnetic resonance imaging tagging.
Frits W Prinzen;William C Hunter;Bradley T Wyman;Elliot R McVeigh.
Journal of the American College of Cardiology (1999)
Measurement of radiotracer concentration in brain gray matter using positron emission tomography: MRI-based correction for partial volume effects.
Hans W. Müller-Gärtner;Jonathan M. Links;Jerry L. Prince;R. Nick Bryan.
Journal of Cerebral Blood Flow and Metabolism (1992)
Phase-sensitive inversion recovery for detecting myocardial infarction using gadolinium-delayed hyperenhancement.
Peter Kellman;Andrew E. Arai;Elliot R. McVeigh;Anthony H. Aletras.
Magnetic Resonance in Medicine (2002)
Serial Cardiac Magnetic Resonance Imaging of Injected Mesenchymal Stem Cells
Jonathan M. Hill;Alexander J. Dick;Venkatesh K. Raman;Richard B. Thompson.
Magnitude and Time Course of Microvascular Obstruction and Tissue Injury After Acute Myocardial Infarction
Carlos E. Rochitte;João A. C. Lima;David A. Bluemke;Scott B. Reeder.
Signal-to-noise measurements in magnitude images from NMR phased arrays.
C.D. Constantinides;E. Atalar;E. McVeigh.
Magnetic Resonance in Medicine (1997)
Systolic improvement and mechanical resynchronization does not require electrical synchrony in the dilated failing heart with left bundle-branch block.
Christophe Leclercq;Owen Faris;Richard Tunin;Jennifer Johnson.
Imaging heart motion using harmonic phase MRI
N.F. Osman;E.R. McVeigh;J.L. Prince.
IEEE Transactions on Medical Imaging (2000)
Adaptive sensitivity encoding incorporating temporal filtering (TSENSE).
Peter Kellman;Frederick H. Epstein;Elliot R. McVeigh.
Magnetic Resonance in Medicine (2001)
Three-dimensional systolic strain patterns in the normal human left ventricle: characterization with tagged MR imaging.
Christopher C. Moore;Carlos H. Lugo-Olivieri;Elliot R. McVeigh;Elias A. Zerhouni.
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