E-Book

Quantitative magnetic resonance imaging [electronic resource]

  • Seiberlich, Nicole, 1980- editor.
  • Academic Press
  • 2020
Quantitative magnetic resonance imaging [electronic resource]
  • 자료유형
    단행본
  • 서명/저자사항
    Quantitative magnetic resonance imaging[electronic resource] / lead editors, Nicole Seiberlich [and six others].
  • 발행사항
    London, England : Academic Press, [2020].
  • 개인저자
    Seiberlich, Nicole, , 1980-, editor.
  • 형태사항
    1 online resource (lxxxvi, 1,006 pages) : illustrations.
  • 일반주제명
    Magnetic resonance imaging.
  • ISBN
    9780128170571, 9780128170588
  • 언어
    영어

초록

Quantitative Magnetic Resonance Imaging is a ‘go-to’ reference for methods and applications of quantitative magnetic resonance imaging, with specific sections on Relaxometry, Perfusion, and Diffusion. Each section will start with an explanation of the basic techniques for mapping the tissue property in question, including a description of the challenges that arise when using these basic approaches. For properties which can be measured in multiple ways, each of these basic methods will be described in separate chapters. Following the basics, a chapter in each section presents more advanced and recently proposed techniques for quantitative tissue property mapping, with a concluding chapter on clinical applications.

목차

Section Introduction
Section 1 Relaxometry
Chapter 1 Biophysical and Physiological Principles of T1 and T2
Chapter 2 Quantitative T1 and T1r Mapping
Chapter 3 Quantitative T2 and T2* Mapping
Chapter 4 Multiproperty Mapping Methods
Chapter 5 Specialized Mapping Methods in the Heart
Chapter 6 Advances in Signal Processing for Relaxometry
Chapter 7 Relaxometry: Applications in the Brain
Chapter 8 Relaxometry: Applications in Musculoskeletal Systems
Chapter 9 Relaxometry: Applications in the Body
Chapter 10 Relaxometry: Applications in the Heart

Section 2 Perfusion and Permeability
Chapter 11 Physical and Physiological Principles of Perfusion and Permeability
Chapter 12 Arterial Spin Labeling MRI: Basic Physics, Pulse Sequences, and Modeling
Chapter 13 Dynamic Contrast-Enhanced MRI: Basic Physics, Pulse Sequences, and Modeling
Chapter 14 Dynamic Susceptibility Contrast MRI: Basic Physics, Pulse Sequences, and modeling
Chapter 15 Applications of Quantitative Perfusion and Permeability in the Brain
Chapter 16 Applications of Quantitative Perfusion and Permeability in the Liver
Chapter 17 Applications of Quantitative Perfusion and Permeability in the Body

Section 3 Diffusion
Chapter 18 Physical and Physiological Principles of Diffusion
Chapter 19 Acquisition of Diffusion MRI Data
Chapter 20 Modeling Fiber Orientations Using Diffusion MRI
Chapter 21 Diffusion MRI Fiber Tractography
Chapter 22 Measuring Microstructural Features Using Diffusion MRI
Chapter 23 Diffusion MRI: Applications in the Brain
Chapter 24 Diffusion MRI: Applications Outside the Brain

Section 4 Fat and Iron Quantification
Chapter 25 Physical and Physiological Properties of Fat
Chapter 26 Physical and Physiological Properties of Iron
Chapter 27 Fat Quantification Techniques
Chapter 28 Applications of Fat Mapping
Chapter 29 Iron Mapping Techniques and Applications

Section 5 Quantification of Other MRI-Accessible Tissue Properties
Chapter 30 Electrical Properties Mapping
Chapter 31 Quantitative Susceptibility Mapping
Chapter 32 Magnetization Transfer
Chapter 33 Chemical Exchange Mapping
Chapter 34 MR Thermometry
Chapter 35 Motion Encoded MRI and Elastography
Chapter 36 Flow Quantification with MRI
Chapter 37 Hyperpolarized Magnetic Resonance Spectroscopy and Imaging