Handbook of MRI Pulse Sequences

Auteur
Xiaohong Joe Zhou is a Professor of Radiology, Bioengineering, and Neurosurgery at The University of Illinois College of Medicine at Chicago and Chief Medical Physicist at the University of Illinois Hospital. He received his B.Sc. degree in physical chemistry from Peking University in China (1984), and Ph.D. degree in magnetic resonance imaging (MRI) from the University of Illinois at Urbana-Champaign (1991). Following postdoctoral training in radiology at Duke University and a brief stay on the faculty of University of Pittsburgh, Dr. Zhou joined the Applied Science Laboratory of General Electric Medical System where he made contributions to fast imaging and diffusion MRI. In 1998, he was recruited to The University of Texas M. D. Anderson Cancer Center as an Assistant Professor and a clinical medical physicist. Since relocating to University of Illinois at Chicago in 2003, Dr. Zhou has been conducting MRI research in the areas of diffusion imaging, cancer imaging, neuroimaging, and pulse sequence development. He is a board-certified medical physicist, a Fellow of ISMRM, a Fellow of AIMBE, and a recipient of Distinguished Investigator Award by the Academy for Radiology and Biomedical Imaging Research. Kevin King was an imaging scientist for GE Healthcare for 34 years from 1983 to 2017. He developed CT calibration and reconstruction algorithms from 1983 to 1991. The CT work included calibration methods to compensate for X-ray detector and source imperfections, dual energy CT, and helical reconstruction algorithms. From 1991 until his retirement in 2017 he developed MR calibration and reconstruction algorithms. The MR work included methods for calibration and measurement of eddy currents, spiral scanning, parallel imaging and compressed sensing. In addition to numerous publications, patents, internal GE technical notes and conference presentations, he also coauthored a book Handbook of MRI Pulse Sequences. He is currently enjoying his retirementWilliam Grissom is an associate professor of Biomedical Engineering and Radiology & Radiological Sciences at Vanderbilt University. He trained at the University of Michigan and Stanford University, and prior to joining Vanderbilt he was a Research Engineer at GE Global Research in Munich, Germany. He is an expert in MR technology and has considerable experience in the design of radiofrequency pulses, image reconstructions, and hardware for very low to ultra-high field MRI scannersLeslie Ying is the Furnas Chair Professor of Biomedical Engineering and Electrical Engineering at University at Buffalo, the State University of New York. She received her B.E. in Electronics Engineering from Tsinghua University, China in 1997 and both her M.S. and Ph.D. in Electrical Engineering from the University of Illinois at Urbana - Champaign in 1999 and 2003, respectively. Prior to joining University at Buffalo in 2012, she was on the faculty of Electrical Engineering and Computer Science at the University of Wisconsin Milwaukee. Her research interests include magnetic resonance imaging, compressed sensing, image reconstruction, and machine learning. She has contributed to the advancement of various biological and medical imaging modalities using computational methods. Dr. Ying received a CAREER award from the National Science Foundation in 2009. She was elected as an Administrative Committee member of IEEE Engineering in Medicine and Biology Society in 2013-2015. She served on the editorial board of IEEE Transactions on Biomedical Engineering, Magnetic Resonance in Medicine, and Scientific Reports. She is currently the Editor-in-Chief of IEEE Transactions on Medical Imaging. She is a Fellow of AIMBE.Matt Bernstein received his Ph.D. in theoretical nuclear physics in 1985 from the University of Wisconsin. From 1987-1998, he served first as Senior Software Designer and then later as Senior Physicist at GE Medical Systems, developing novel techniques for MR. He has been awarded 36 US patents over his career. Currently he is a board-certified Medical Physicist and researcher at Mayo Clinic, where he is a Full Professor in the Department of Radiology, with a joint appointment in the Department of Physiology and Biomedical Engineering. Recently the research group he leads developed a novel Compact 3T scanner in collaboration with GE Global Research, and he is currently serving as PI of a 5-year, NIH U01 grant for this program. Dr Bernstein was Editor-in-Chief of Magnetic Resonance in Medicine from 2011-2019, and chaired the International Society for Magnetic Resonance (ISMRM) Engineering Study Group. He is a Fellow of the ISMRM and AIMBE, and is a Distinguished Investigator of the Academy for Radiology & Biomedical Imaging Research. He also served on the Board of Directors of the American Board of Medical Physics, the Board of Trustees of the ISMRM, as well as on several NIH Study Sections. Dr Bernstein has authored over 130 peer-reviewed papers, 250 conference abstracts, and co-authored the book Thinking about equations: A practical guide for developing mathematical intuition in the physical sciences and engineering. According to Google Scholar, his work has been cited approximately 15,000 times.

Texte du rabat
Magnetic Resonance Imaging (MRI) is among the most important medical imaging techniques available today. Each of these scanners is capable of running many different "pulse sequences". These sequences are governed by physics and engineering principles and implemented by software programs that control the MRI hardware. To utilize an MRI scanner to the fullest extent, a conceptual understanding of its pulse sequences is crucial. The newly updated second edition of Handbook of MRI Pulse Sequences, Second Edition includes an increased 92 self-contained sections, each section focusing on a single subject. A new section on detailing the advanced pulse sequence techniques, covers a variety of basic and advanced image reconstruction methods. The extensive topic coverage and cross-referencing makes this book ideal for beginners learning the building blocks of MRI pulse sequence design, as well as for experienced professionals who are seeking deeper knowledge of a particular technique.

Contenu

Part I: Background

1. Tools

Part II: RF Pulses

2. RF Pulse Shapes
3. Basic RF Pulse Functions
4. Spectral RF Pulses
5. Spatial RF Pulses
6. Advanced RF Pulses

Part III: Gradients

8. Gradient Lobe Shapes
9. Imaging Gradients
10. Motion Sensitizing Gradients
11. Correction Gradients

Part IV: Data Acquisition and k-space Sampling

12. Signal Acquisition and k-Space Sampling
13. Management of Physiologic Motion

Part V: IMAGE RECONSTRUCTION

14. Common Image Reconstruction Techniques
15. Selected Advanced Image Reconstruction Techniques

Part VI: Pulse sequences

16. Basic Pulse Sequences
17. Angiographic Pulse Sequences
18. Echo Train Pulse Sequences
19. Non-Cartesian Pulse Sequences
20. Pulse Sequences for Advanced Applications
21. Selected Measurement Tools