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Full-Text Articles in Biomedical Engineering and Bioengineering
Myocardial T1 Mapping Techniques For Quantification Of Myocardial Fibrosis, Xiaopeng Zhou
Myocardial T1 Mapping Techniques For Quantification Of Myocardial Fibrosis, Xiaopeng Zhou
ETD Archive
Identifying and quantifying diffuse myocardial fibrosis is important to provide insights into the relationship between myocardial fibrosis, diastolic and systolic dysfunction, as well as clinical outcomes. T1 mapping is a promising technique for noninvasively identifying diffuse myocardial fibrosis in heart failure. A quantitative T1 map provides sensitivity to the full range of T1 values and is advantageous over the traditional T1-weighted imaging by reducing the reliance on visual interpretation of the signal intensity in the myocardium. However, in-vivo myocardial T1 quantification is challenging because of cardiac and respiratory motion. During the past few years, a variety of T1 mapping techniques, …
7d Cardiac Flow Mri: Techniques & Automation Of Reconstruction, Michael G. Ambrosia
7d Cardiac Flow Mri: Techniques & Automation Of Reconstruction, Michael G. Ambrosia
ETD Archive
Advances in magnetic resonance imaging to quantify the blood flow in the heart and major vessels stemming from the heart has recently allowed for advanced clinical applications for patients suffering from cardiac valve problems and aortic abnormalities. 7D cardiac flow quantification is relatively new, but has already shown potential in several clinical applications, including bicuspid valve and aortic coarctation characterization. In addition radiologists diagnosing valvular regurgitation may benefit from insight provided by the 7D cardiac flow quantification protocol. 7D cardiac flow quantification using magnetic resonance imaging will provide direction flow quantification in the anterior / posterior, head / foot, and …
A Left Ventricular Motion Phantom For Cardiac Magnetic Resonance Imaging, Mehmet Ersoy
A Left Ventricular Motion Phantom For Cardiac Magnetic Resonance Imaging, Mehmet Ersoy
ETD Archive
The mammalian left ventricle (LV) has two distinct motion patterns: wall thickening and rotation. The purpose of this study was to design and build a low-cost, non-ferromagnetic LV motion phantom, for use with cardiac magnetic resonance imaging (MRI), that is able to produce physiologically realistic LV wall thickening and rotation. Cardiac MRI is continuously expanding its range of techniques with new pulse sequences, including new tissue tagging techniques which allow intra-myocardial deformation to be visualized. An essential step in the development of new cardiac MRI techniques is validating their performance in the presence of motion. MRI-compatible dynamic motion phantoms are …