Introduction to functional magnetic resonance imaging : principles and techniques

In An Introduction to Functional Magnetic Resonance Imaging, Richard Buxton, a leading authority, provides an invaluable introduction to how fMRI works, from basic principles and the underlying physics and physiology, to newer techniques such as arterial spin labeling and diffusion tensor imaging. The supplementary CD-ROM contains all the figures from the book as PowerPoint files, together with movies of cross-sectional anatomical MR images and a library of all the MR images used in the movies as individual Tiff files. These comprise the following sets: high resolution volume imaging sets in three orientations; T1-weighted spin-echo (transverse); T2-weighted spin-echo (transverse); and T1-weighted true inversion recovery (sagittal). As a supplement to the book, and a resource for teachers and researchers, this combination of text and dual platform CD is invaluable.

• Introduction
• Part I. An Overview of Functional Magnetic Resonance Imaging: I A. Introduction to Functional Neuroimaging: 1. Energy metabolism in the brain
• 2. Cerebral blood flow
• 3. Brain activation
• I B. Introduction to Functional Magnetic Resonance Imaging: 4. Nuclear magnetic resonance
• 5. Magnetic resonance imaging
• 6. Imaging functional activity
• Part II. Principles of Magnetic Resonance Imaging: II A. The Nature of the Magnetic Resonance Signal: 7. Basic physics of magnetism and NMR
• 8. Relaxation and contrast in MRI
• 9. Diffusion and the MR signal
• II B. Magnetic Resonance Imaging: 10. Mapping the MR signal
• 11. MRI techniques
• 12. Noise and artifacts in MR images
• Part III. Principles of Functional Magnetic Resonance Imaging: III A. Perfusion Imaging: 13. Principles of tracer kinetics
• 14. Contrast agent techniques
• 15. Arterial spin labeling techniques
• III B. Blood Oxygenation Level Dependent (BOLD) Imaging: 16. The nature of the BOLD effect
• 17. Mapping brain activation with BOLD-fMRI
• 18. Statistical analysis of BOLD data
• 19. Efficient design of BOLD experiments
• Appendix: the physics of NMR
• Index
• CD-ROM.

In An Introduction to Functional Magnetic Resonance Imaging, Richard Buxton, a leading authority, provides an invaluable introduction to how fMRI works, from basic principles and the underlying physics and physiology, to newer techniques such as arterial spin labeling and diffusion tensor imaging. This CD-ROM contains all the figures from the book as PowerPoint files, together with movies of cross-sectional anatomical MR images and a library of all the MR images used in the movies as individual Tiff files. These comprise the following sets: high resolution volume imaging sets in three orientations; T1-weighted spin-echo (transverse); T2-weighted spin-echo (transverse); and T1-weighted true inversion recovery (sagittal). As a supplement to the book, and a resource for teachers and researchers, this dual platform CD is invaluable.

Functional Magnetic Resonance Imaging (fMRI) is now a standard tool for mapping activation patterns in the human brain. This highly interdisciplinary field involves neuroscientists and physicists as well as clinicians, and the range, flexibility and sophistication of the techniques being used are increasing rapidly. In this book, Richard Buxton, a leading authority on fMRI, provides an invaluable introduction to how fMRI works, from basic principles and the underlying physics and physiology, to newer techniques such as arterial spin labeling and diffusion tensor imaging. The book also includes discussion of how fMRI relates to other imaging techniques (such as Positron Emission Tomography, or PET) and a guide to the statistical analysis of fMRI data. This book will be useful both to the experienced researcher using fMRI, and the clinician or researcher with no previous knowledge of the technology.

• Introduction
• Part I. An Overview of Functional Magnetic Resonance Imaging: I A. Introduction to Functional Neuroimaging: 1. Energy metabolism in the brain
• 2. Cerebral blood flow
• 3. Brain activation
• I B. Introduction to Functional Magnetic Resonance Imaging: 4. Nuclear magnetic resonance
• 5. Magnetic resonance imaging
• 6. Imaging functional activity
• Part II. Principles of Magnetic Resonance Imaging: II A. The Nature of the Magnetic Resonance Signal: 7. Basic physics of magnetism and NMR
• 8. Relaxation and contrast in MRI
• 9. Diffusion and the MR signal
• II B. Magnetic Resonance Imaging: 10. Mapping the MR signal
• 11. MRI techniques
• 12. Noise and artifacts in MR images
• Part III. Principles of Functional Magnetic Resonance Imaging: III A. Perfusion Imaging: 13. Principles of tracer kinetics
• 14. Contrast agent techniques
• 15. Arterial spin labeling techniques
• III B. Blood Oxygenation Level Dependent (BOLD) Imaging: 16. The nature of the BOLD effect
• 17. Mapping brain activation with BOLD-fMRI
• 18. Statistical analysis of BOLD data
• 19. Efficient design of BOLD experiments
• Appendix: the physics of NMR
• Index.