Rad Tech's Guide to MRI
Basic Physics, Instrumentation, and Quality Control
Rad Tech's Guides
2. Edition February 2020
144 Pages, Softcover
Handbook/Reference Book
Further versions
The second edition of Rad Tech's Guide to MRI provides practicing and training technologists with a succinct overview of magnetic resonance imaging (MRI). Designed for quick reference and examination preparation, this pocket-size guide covers the fundamental principles of electromagnetism, MRI equipment, data acquisition and processing, image quality and artifacts, MR Angiography, Diffusion/Perfusion, and more.
Written by an expert practitioner and educator, this handy reference guide:
* Provides essential MRI knowledge in a single portable, easy-to-read guide
* Covers instrumentation and MRI hardware components, including gradient and radio-frequency subsystems
* Provides techniques to handle flow imaging issues and improve the quality of MRIs
* Explains the essential physics underpinning MRI technology
Rad Tech's Guide to MRI is a must-have resource for student radiographers, especially those preparing for the American Registry of Radiation Technologist (ARRT) exams, as well as practicing radiology technologists looking for a quick reference guide.
Instrumentation: Magnets 1
Instrumentation: RF Subsystem 6
Instrumentation: Gradient Subsystem 8
2. Fundamental Principles 11
Electromagnetism: Faraday's Law of Induction 11
Magnetism 12
Behavior of Hydrogen in a Magnetic Field 14
3. Production of Magnetic Resonance Signal 19
4. Relaxation and Tissue Characteristics 23
T2-Relaxation 23
T1-Relaxation 24
Proton Density 24
T2* (Pronounced "T2 star") 25
5. Data Acquisition and Image Formation 27
Pulse Sequences 27
Image Contrast Control 30
Image Formation 42
Data Acquisition 43
Scan Time 50
Controlling Image Quality with FSE 57
6. Magnetic Resonance Image Quality 61
Spatial Resolution 61
Signal-to-Noise Ratio (SNR) 63
7. Artifacts 75
Chemical Shift (Water and Fat in Different Voxels) 75
Chemical Shift (Water and Fat in the Same Voxel) 77
Magnetic Susceptibility 79
Motion and Flow 81
Spatial Presaturation 82
Gradient Moment Nulling (Flow Compensation) 84
Compensation for Respiration 84
Cardiac Compensation 86
Aperiodic Motion 88
Aliasing 89
Gibbs and Truncation Artifact 91
Radio-Frequency Artifacts 92
Gradient Malfunctions 93
Image Shading 93
Inadequate System Tuning 94
Reconstruction Artifacts 94
8. Flow Imaging 97
Flow Patterns 97
Magnetic Resonance Angiography (Non Contrast) 98
Reduction of Flow Artifacts 102
Signal Loss in MRA 102
Two-Dimensional and Three-Dimensional Time-of-Flight 103
Signal Loss with Two-Dimensional TOF 104
Three-Dimensional TOF 106
Signal Loss with Three-Dimensional TOF 108
PC Techniques 109
Contrast Enhanced MRA (CE-MRA) 113
9. Diffusion and Perfusion Imaging 117
Diffusion-Weighted Imaging (DWI) 117
10. Gadolinium-Based Contrast Agents 125
Characteristics, Composition and Structure 125
Index 129
