Clinical MR imaging and physics: A tutorial

This document was uploaded by one of our users. The uploader already confirmed that they had the permission to publish it. If you are author/publisher or own the copyright of this documents, please report to us by using this DMCA report form.

Simply click on the Download Book button.

Yes, Book downloads on Ebookily are 100% Free.

Sometimes the book is free on Amazon As well, so go ahead and hit "Search on Amazon"

Keywords Spin › Electromagnetic radiation › Resonance › Nucleus › Hydrogen › Proton › Certain atomic nuclei possess inherent magnetic Let us summarize the MRI procedure. Te patient properties called spin, and can interact with electro- is placed in a magnetic feld and becomes temporarily 1 magnetic (EM) radiation through a process called magnetized. Resonance is achieved through the - resonance. When such nuclei absorb EM energy they plication of specifc pulses of EM radiation, which is proceed to an excited, unstable confguration. Upon absorbed by the patient. Subsequently, the excess - return to equilibrium, the excess energy is released, ergy is liberated and measured. Te captured signal producing the MR signal. Tese processes are not is processed by a computer and converted to a gray random, but obey predefned rules. scale (MR) image. Te simplest nucleus is that of hydrogen (H), con- Why do we need to place the patient in a m- sisting of only one particle, a proton. Because of its net? Because the earth’s magnetic feld is too weak to abundance in humans and its strong MR signal, H be clinically useful; it varies from 0. 3–0. 7 Gauss (G). is the most useful nucleus for clinical MRI. Tus, foC r urrent clinical MR systems operate at low, mid or our purposes, MRI refers to MRI of hydrogen, and for h igh feld strength ranging from 0. 1 to 3.

Author(s): Haris S. Chrysikopoulos (auth.)
Edition: 1
Publisher: Springer-Verlag Berlin Heidelberg
Year: 2009

Language: English
Pages: 176
Tags: Imaging / Radiology; Diagnostic Radiology

Front Matter....Pages I-IX
Resonance....Pages 1-1
Electromagnetic Fields....Pages 2-2
Macroscopic Magnetization....Pages 3-4
Macroscopic Magnetization Revisited....Pages 5-6
Excitation Phenomena....Pages 7-8
T1 Relaxation (Longitudinal or Spin-Lattice Relaxation)....Pages 9-10
T2 Relaxation (Transverse or Spin–Spin Relaxation)....Pages 11-12
Magnetic Substrates of T1 Relaxation....Pages 13-15
Magnetic Substrates of T2 Relaxation....Pages 16-16
Proton (Spin) Density Contrast....Pages 17-17
Partial Saturation....Pages 18-18
Free Induction Decay....Pages 19-19
Spin Echo....Pages 20-21
Integration of T1, T2, and Proton Density Phenomena....Pages 22-24
Inversion Recovery....Pages 25-27
Image Formation – Fourier Transform – Gradients....Pages 28-31
Gradient Echo Imaging....Pages 32-38
Pulse Sequences....Pages 39-39
Fast or Turbo Spin Echo Imaging....Pages 40-42
Selective Fat Suppression....Pages 43-51
Chemical Shift Imaging....Pages 52-55
Magnetization Transfer Contrast....Pages 56-61
Diffusion....Pages 62-69
Artifacts....Pages 70-80
Noise....Pages 81-81
Imaging Time....Pages 82-82
Resolution....Pages 83-84
Contrast Agents....Pages 85-89
Blood Flow....Pages 90-93
MR Angiography....Pages 94-108
Basics of MR Examinations and Interpretation....Pages 109-163
Back Matter....Pages 164-176