PRZEDMIOTEM OFERTY JEST KOD DOSTĘPOWY DO KSIĄŻKI ELEKTRONICZNEJ (EBOOK)
KSIĄŻKA JEST DOSTĘPNA NA ZEWNĘTRZNEJ PLATFORMIE. KSIĄŻKA NIE JEST W POSTACI PLIKU.
ESSENTIAL CONCEPTS IN MRI
A concise and complete introductory treatment of NMR and MRI
Essential Concepts in MRI delivers the first comprehensive look at magnetic resonance imaging with a practical focus on nuclear magnetic resonance spectroscopy applications. The book includes the essential components of MRI and NMR and is written for anyone new to the field of MRI who seeks to gain a complete understanding of all four essential components of MRI: physics theory, instrumentation, spectroscopy, and imaging.
Highly visual and including numerous full color figures that provide crucial graphical descriptions of key concepts discussed in the book, Essential Concepts in MRI includes discussions of quantitative and creative MRI, as well as spatial mapping in MRI and the effects of the field gradient and k-space imaging. The book also covers:
- A thorough introduction to essential concepts in nuclear magnetic resonance, including classical descriptions of NMR and quantum mechanical descriptions of NMR
- Comprehensive explorations of essential concepts in NMR instrumentation, including magnets, radio-frequency coils, transmitters, and receivers
- Practical discussions of essential concepts in NMR spectroscopy, including simple 1D spectroscopy, double resonance, and dipolar interactions in two-spin systems
- In-depth examinations of essential concepts in MRI, including the design of MRI pulse sequences and the elements of MRI instrumentation, with a special focus on quantitative MRI
Essential Concepts in MRI is a must-read reference for upper-level undergraduate and postgraduate students in the physical and medical sciences, especially radiology, MRI, and imaging courses. It is also essential for students and researchers in the biomedical sciences and engineering.
- Autorzy: Yang Xia
- Wydawnictwo: Wiley Global Research (STMS)
- Data wydania: 2022
- Wydanie: 1
- Liczba stron:
- Forma publikacji: ePub (online)
- Język publikacji: angielski
- ISBN: 9781119798248
BRAK MOŻLIWOŚCI POBRANIA PLIKU. Drukowanie: OGRANICZENIE DO 10 stron. Kopiowanie: OGRANICZENIE DO 2 stron.
- Cover
- Title page
- Copyright
- Dedication
- Preface
- Chapter 1 Introduction
- 1.1 Introduction
- 1.2 Major Steps in an NMR or MRI Experiment, and Two Conventions in Direction
- 1.3 Major Milestones in the History of NMR and MRI
- 1.4 The Organization for a One-semester Course
- Part I Essential Concepts in NMR
- Chapter 2 Classical Description of Magnetic Resonance
- 2.1 Fundamental Assumptions
- 2.2 Nuclear Magnetic Moment
- 2.3 The Time Evolution of Nuclear Magnetic Moment
- 2.4 Macroscopic Magnetization
- 2.5 Rotating Reference Frame
- 2.6 Spin Relaxation Processes
- 2.7 Bloch Equation
- 2.8 Fourier Transform and Spectral Line Shapes
- 2.9 CW NMR
- 2.10 Radio-frequency Pulses in NMR
- 2.11 FT NMR
- 2.12 Signal Detection in NMR
- 2.13 Phases of the NMR Signal
- Chapter 3 Quantum Mechanical Description of Magnetic Resonance
- 3.1 Nuclear Magnetism
- 3.2 Energy Difference
- 3.3 Macroscopic Magnetization
- 3.4 Measurement of the x Component of Angular Momentum
- 3.5 Macroscopic Magnetization for Spin 1/2
- 3.6 Resonant Excitation
- 3.7 Mechanisms of Spin Relaxation
- Chapter 4 Nuclear Interactions
- 4.1 Dipolar Interaction
- 4.2 Chemical Shift Interaction
- 4.3 Scalar Interaction
- 4.4 Quadrupole Interaction
- 4.5 Summary of Nuclear Interactions
- Part II Essential Concepts in NMR Instrumentation
- Chapter 5 Instrumentation
- 5.1 Magnets
- 5.2 Radio-frequency Coil, Its Resonant Circuitry, and the Probe
- 5.3 Frequency Management
- 5.4 Transmitter
- 5.5 Receiver
- 5.6 Pulse Programmer and Computer
- 5.7 Other Components
- Chapter 6 NMR Experimental
- 6.1 Shimming
- 6.2 Preparing Samples
- 6.3 Pulse Sequences and FID
- 6.4 Digitization Rate and Digital Resolution
- 6.5 Dynamic Range
- 6.6 Phase Cycling
- 6.7 Data Accumulation
- 6.8 Pre-FFT Processing Techniques
- 6.9 Fast Fourier Transform
- 6.10 Post-FFT Processing
- 6.11 Signal-to-Noise Ratio
- Chapter 7 Spin Manipulations by Pulse Sequences
- 7.1 SINGLE PULSE: 90°Ix, 90°Iy, 90°I-x, 90°I-y
- 7.2 Inversion Recovery Sequence, Saturation Recovery Sequence, and T1 Relaxation
- 7.3 Spin-Echo Sequence (Hahn Echo) and T2 Relaxation
- 7.4 CPMG Echo Train
- 7.5 Stimulated Echo Sequence
- 7.6 SPIN-LOCKING AND T1? RELAXATION
- 7.7 How to Select the Delays in Relaxation Measurement
- Part III Essential Concepts in NMR Spectroscopy
- Chapter 8 First-order 1D Spectroscopy
- 8.1 Nomenclature of the Spin System
- 8.2 Peak Shift – the Effect of Chemical Shift
- 8.3 Peak Area – Reflecting the Number of Protons
- 8.4 Peak Splitting – the Consequence of J Coupling
- 8.5 Examples of 1D Spectra
- Chapter 9 Advanced Topics in Spectroscopy
- 9.1 Double Resonance
- 9.2 Dipolar Interaction in a Two-spin System
- 9.3 Magic Angle
- 9.4 Chemical Exchange
- 9.5 Magnetization Transfer
- 9.6 Selective Polarization Inversion/Transfer
- 9.7 Radiation Damping
- Chapter 10 2D NMR Spectroscopy
- 10.1 Essence of 2D NMR Spectroscopy
- 10.2 COSY – Correlation Spectroscopy
- 10.3 J-resolved Spectroscopy
- 10.4 Examples of 2D NMR Spectroscopy
- Part IV Essential Concepts in MRI
- Chapter 11 Effect of the Field Gradient and k-space Imaging
- 11.1 Spatially Encoding Nuclear Spin Magnetization
- 11.2 k Space in MRI
- 11.3 Mapping of k Space
- 11.4 Gradient Echo
- Chapter 12 Spatial Mapping in MRI
- 12.1 Slice Selection in 2D MRI
- 12.2 Reading a Graphical Imaging Sequence
- 12.3 2D Filtered Back-Projection Reconstruction
- 12.4 2D Fourier Imaging Reconstruction
- 12.5 Sampling Patterns Between the Cartesian and Radial Grids
- 12.6 3D Imaging
- 12.7 Fast Imaging in MRI
- 12.8 Ultra-short Echo and ZTE MRI
- 12.9 MRI in Other Dimensions (4D, 1D, and One Voxel)
- 12.10 Resolution in MRI
- Chapter 13 Imaging Instrumentation and Experiments
- 13.1 Shaped Pulses
- 13.2 The Gradient Units
- 13.3 Instrumentation Configurations for MRI
- 13.4 Imaging Parameters in MRI
- 13.5 Image Processing Software
- 13.6 Best Test Samples for MRI
- Part V Quantitative and Creative MRI
- Chapter 14 Image Contrast in MRI
- 14.1 Non-trivial Relationship Between Spin Density and Image Intensity
- 14.2 Image Contrast in MRI
- 14.3 How to Obtain Useful Information from Image Contrast?
- 14.4 Magnetization-prepared Sequences in Quantitative MRI
- Chapter 15 Quantitative MRI
- 15.1 Quantitative Imaging of Velocity v and Molecular Diffusion D
- 15.2 Quantitative Imaging of Relaxation Times T1, T2, T1?
- 15.3 Quantitative Imaging of Chemical Shift ?
- 15.4 Secondary Image Contrasts in MRI 259
- 15.5 Potential Issues and Practical Strategies in Quantitative MRI
- Chapter 16 Advanced Topics in Quantitative MRI
- 16.1 Anisotropy and Tensor Properties in Quantitative MRI
- 16.2 Multi-Component Nature in Quantitative MRI
- 16.3 Quantitative Phase Information in the FID Data – SWI and QSM
- 16.4 Functional MRI (fMRI)
- 16.5 Optical Pumping and Hyperpolarization in MRI
- Chapter 17 Reading the Binary Data
- 17.1 Formats of Data
- 17.2 Formats of Data Storage
- 17.3 Reading Unknown Binary Data
- 17.4 Examples of Specific Formats
- Appendices
- Appendix 1 Background in Mathematics
- A1.1 Elementary Mathematics
- A1.2 Fourier Transform
- Appendix 2 Background in Quantum Mechanics
- A2.1 Operators
- A2.2 Expansion of a Wave Function
- A2.3 Spin Operator I
- A2.4 Raising and Lowering Operators I+ and I-
- A2.5 Spin-1/2 Operator (in the Formalism of Pauli’s Spin Matrices)
- A2.6 Density Matrix Operator ?
- Appendix 3 Background in Electronics
- A3.1 Ohm’s Law for DC and AC Circuits
- A3.2 Electronics at Radio Frequency
- Appendix 4 Sample Syllabi for a One-semester Course
- Appendix 5 Homework Problems
- Index
- End User License Agreement
W tej ofercie kupujesz kod dostępowy umożliwiający dostęp do wskazanej treści. Kod umożliwia dostęp do treści za pomocą przeglądarki WWW, dedykowanej aplikacji iOS (Apple) ze sklepu App Store lub dedykowanej aplikacji Android ze sklepu Play. Kod oraz instrukcje otrzymasz pocztą elektroniczną niezwłocznie po zaksięgowaniu płatności. Brak możliwości pobrania pliku.
Na podstawie art. 38 pkt 13 Ustawy z dnia 30 maja 2014 roku o prawach konsumenta realizując kod dostępowy rezygnujesz z prawa do odstąpienia od umowy zawartej na odległość.
Typ licencji: licencja wieczysta.
BRAK MOŻLIWOŚCI POBRANIA PLIKU.
NIE PRZESYŁAMY PLIKÓW E-MAILEM.