Details

MRI Physics


MRI Physics

Tech to Tech Explanations
1. Aufl.

von: Stephen J. Powers

40,99 €

Verlag: Wiley-Blackwell
Format: PDF
Veröffentl.: 12.03.2021
ISBN/EAN: 9781119615057
Sprache: englisch
Anzahl Seiten: 416

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Beschreibungen

<b>MRI</b> PHYSICS <p><b>MRI</b> PHYSICS<p><b>TECH TO TECH EXPLANATIONS</b><p>Technologists must have a solid understanding of the physics behind Magnetic Resonance Imaging (MRI), including safety, the hows and whys of the quantum physics of the MR phenomenon, and how to competently operate MRI scanners. Generating the highest quality images of the human body involves thorough knowledge of scanner hardware, pulse sequences, image contrast, geometric parameters, and tissue suppression techniques.<p><i>MRI Physics: Tech to Tech Explanations</i> is designed to help student MRI technologists and radiotherapists preparing for Advanced MRI certification examinations to better understand difficult concepts and topics in a quick and easy manner.<p>Written by a highly experienced technologist, this useful guide provides clear and reader-friendly coverage of what every MR Technologist needs to know. Topics include safety considerations associated with the magnetic field and RF, pulse sequences, artifacts, MRI math, the much-feared gradients, and I.V. contrast.<ul><li>Provides basic guidance on safety considerations, protocols options, critical thinking, and image contrast optimization</li><li>Simplifies the challenging topic of MRI physics using straightforward language and clear explanations</li><li>Covers content for American Registry of Radiologic Technologists (ARRT) and Continuing Qualifications Requirements (CQR) exams</li><li>Features numerous illustrations and photographs of various MRI concepts, pulse sequence design, artifacts, and the application of concepts in clinical settings</li></ul><p><i>MRI Physics: Tech to Tech Explanations</i> is a must-have resource for the experienced and training MRI technologist, medical students, and radiology residency rotations.
<p>About the Author xv</p> <p>Preface xvii</p> <p>Acknowledgements xix</p> <p>Introduction 1</p> <p><b>1 </b><b>Hardware: Magnet Types and Coils 15</b></p> <p>Magnets 15</p> <p>Coils 17</p> <p><b>2 </b><b>The Basics 23</b></p> <p>Why the Hydrogen Molecule? 24</p> <p>The Net Magnetization Vector 26</p> <p>MRI is a Sequence of Events 27</p> <p>Free Induction Decay (FID) 32</p> <p>Relaxation 33</p> <p>Proton Density 38</p> <p>Image Contrast 38</p> <p>The IQ Triangle: Contrast, SNR, Resolution 39</p> <p>B0 and B1 43</p> <p>Free and Bound Protons 44</p> <p><b>3 </b><b>Image Weighting 47</b></p> <p>Where Does Image Weighting Come From? 48</p> <p>Time of Repetition (TR) 50</p> <p>Time of Echo (TE) 52</p> <p>TE and TR 54</p> <p>Why Different TR Ranges for Different Field Strengths? 54</p> <p>How Does TR Control T1? 55</p> <p>What Does TR Affect? 56</p> <p>Interpreting the T1 Relaxation Curve 57</p> <p>Time of Repetition: Effects of the TR 57</p> <p>TE: The T1 and T2 of it 58</p> <p>Interpreting the T2 Relaxation Curve 60</p> <p>Effects of TE on Image Contrast 62</p> <p>What Do the Lines on the Curves Really Mean Anyway? 62</p> <p>One Last Weighting Triangle 65</p> <p>T1 and T2 Contrast Review 66</p> <p><b>4 </b><b>Introduction to the Basic Pulse Sequences 69</b></p> <p>What is a Pulse Sequence? 69</p> <p>Spin Echo (SE) 70</p> <p>Gradient Echo/Gradient Recalled Echo (GRE) 73</p> <p>Line Diagram Anatomy 74</p> <p>The Ernst Angle 77</p> <p><b>5 </b><b>Multi Echo Spin Echo Sequence 81</b></p> <p>Introduction to <i>k</i>-Space 82</p> <p><i>k</i>-Space: Phase Encoding 85</p> <p>With FSE, Watch the Speed Limit! 86</p> <p><i>k-</i>Space, ETL, and Image Contrast 87</p> <p>Filling <i>k</i>-Space 89</p> <p>Pros and Cons of FSE 89</p> <p>Another Way to View T2* and 180<sup>°</sup>s 91</p> <p>Where Do Relaxation and Decay Curves Come From? 92</p> <p>A T2* Curve Compared to the T2 Curve 93</p> <p>Metal Artifact Reduction (MARS) 94</p> <p>Driven Equilibrium: A “Forced T1” 95</p> <p>3D FSE: CUBE/SPACE/VISTA 97</p> <p>Single Shot FSE/HASTE 98</p> <p><b>6 </b><b>Tissue Suppression 105</b></p> <p>Tissue Saturation versus Suppression 107</p> <p>Inversion Recovery – Part One: STIR 108</p> <p>Inversion Recovery: STIR with Vectors 109</p> <p>Inversion Recovery Part Two: T2 FLAIR 113</p> <p>IR Sequences: T1 and T2 FLAIR 116</p> <p>IR Weightings: STIR, T1 and T2 FLAIR 117</p> <p>Inversion Recovery – Part Two 119</p> <p>The Rupture View 120</p> <p>Tissue Saturation: Chemical Shift 121</p> <p>Chemical Saturation at Low Fields 123</p> <p>Tissue Saturation: SPAIR and SPIR 124</p> <p>The Dixon Technique 126</p> <p>Water Excitation 126</p> <p>Saturation Pulses or Bands 129</p> <p>Subtractions 131</p> <p>Magnetization Transfer 135</p> <p>IR Prepped Sequences 137</p> <p>How is an RF Pulse Selective or Non-Selective? 140</p> <p>Water Excitation Sequences 142</p> <p><b>7 </b><b>The Gradient Echo Sequence 145</b></p> <p>GRE Sequence Structure 147</p> <p>Phase Dispersion and Gradient Reversal 148</p> <p>Analog to Digital Converter (ADC) 149</p> <p>GRE Sequence Image Weighting 149</p> <p>Two Different Kinds of T2 Relaxation 152</p> <p>The GRE Weighting Triangle 153</p> <p>GRE and SE Differences 156</p> <p>Different Gradient Echo Types 157</p> <p>In and Out of Phase TEs 161</p> <p>In Phase/Out of Phase at 1.5 T 163</p> <p><b>8 </b><b>Gradient Echo Magnetic Resonance Angiography 167</b></p> <p>Time of Flight MRA 168</p> <p>TOF Angiography: Two Golden Rules 171</p> <p>Types of MRA Sequences 171</p> <p>TOF Concept in MRA versus MRV 172</p> <p>2D versus 3D 172</p> <p>2D TOF MRAs 175</p> <p>3D TOF MRAs 176</p> <p>In-Plane Saturation 178</p> <p>In-Plane Saturation Avoidance 179</p> <p>Magnetization Transfer (MT) 181</p> <p>Options for Better MRAs 183</p> <p>Phase Contrast MRA 185</p> <p><b>9 </b><b><i>k</i>-Space 191</b></p> <p>What Is Fourier Transform? 192</p> <p><i>k</i>-Space Filling 192</p> <p><b>10 </b><b>Echo Planar Sequences 203</b></p> <p>Diffusion Weighted Imaging 205</p> <p>Diffusion Tensor Imaging or White Matter Tractography 215</p> <p>Susceptibility Weighted Imaging 216</p> <p>Brain Perfusion 218</p> <p>Arterial Spin Labeling 222</p> <p>Spectroscopy 225</p> <p><b>11 </b><b>Geometric Parameters: Trade-offs and Effects on Image Quality 231</b></p> <p>Field of View (FOV) Is Your Film Size 232</p> <p>Nex, ACQ, NSA, and SNR 235</p> <p>Scan Matrix 237</p> <p>Frequency Matrix 237</p> <p>Echo Train Length 238</p> <p>Echo Spacing 239</p> <p>Echo Train Balancing 240</p> <p>Slice Thickness and Slice Gap 242</p> <p>Fractional Echo 243</p> <p>Bandwidth 244</p> <p>Rectangular (Rec.) FOV 249</p> <p>No Phase Wrap/Phase Oversampling/Fold-Over Suppression 251</p> <p>Concatenations or Acquisitions 254</p> <p>Sequential Order Acquisition 255</p> <p><b>12 </b><b>Image Artifacts 257</b></p> <p>Motion 258</p> <p>Flow Artifact/Phase Mis-registration 262</p> <p>RF Artifacts 265</p> <p>Wrap/Aliasing/Fold-over Artifact 265</p> <p>Gibbs Artifact (Ringing/Truncation) 268</p> <p>Chemical Shift Artifact 271</p> <p>Cross-talk 276</p> <p>Cross-excitation 278</p> <p>Gradient Warp or Distortion 281</p> <p>Metal Artifacts 281</p> <p>Corduroy Artifact 283</p> <p>Annifact 284</p> <p>Moiré Fringe Artifact or Zebra Artifact 285</p> <p>Magnetic Susceptibility Artifact 286</p> <p>Dielectric Effect or Standing Wave 288</p> <p>Magic Angle Artifact 290</p> <p><b>13 </b><b>Gradients 295</b></p> <p>Physical Gradients 296</p> <p>Logical Gradients 302</p> <p><b>14 </b><b>MRI Math 313</b></p> <p>The Larmor Equation: W<sub>0</sub> = γB<sub>0</sub> 314</p> <p>Acquisitions or Nex or NSA 314</p> <p>Scan Time Equations 315</p> <p>Pixel Size and Voxel Volume 317</p> <p>How to Convert Hz per Pixel to MHz 318</p> <p>In and Out of Phase TEs 319</p> <p>Dixon Method or Technique 320</p> <p>SNR and the 3D Sequence 321</p> <p><b>15 </b><b>Parallel Imaging 325</b></p> <p>Parallel Imaging: What Is It? 325</p> <p>When and Where to Use the Speed 326</p> <p>Parallel Imaging: How Does It Work? 327</p> <p>Parallel Imaging: Pros and Cons 330</p> <p><b>16 </b><b>IV Gadolinium 335</b></p> <p>Why We Use Gad 336</p> <p>How Does Gad Shorten the T1 of Tissues? 337</p> <p>The Blood–Brain Barrier 341</p> <p>Post Contrast T2 FLAIR Imaging 342</p> <p>Imaging Gadolinium 345</p> <p>Eovist<sup>®</sup> 347</p> <p>Glossary 351</p> <p>Suggested Reading 388</p> <p>Index 389 </p>
<p><b>Stephen J. Powers</b>, BSRT (R), (CT), (MR) is currently an MR Technologist for South Coast Hospital Systems in the USA, and former MRI Clinical Applications Specialist for General Electric Health Care. Stephen has over twenty years of classroom, lecture and clinical instructor experience.</p>
<p><b>MRI</b> PHYSICS</p><p><b>TECH TO TECH EXPLANATIONS</b></p><p>Technologists must have a solid understanding of the physics behind Magnetic Resonance Imaging (MRI), including safety, the hows and whys of the quantum physics of the MR phenomenon, and how to competently operate MRI scanners. Generating the highest quality images of the human body involves thorough knowledge of scanner hardware, pulse sequences, image contrast, geometric parameters, and tissue suppression techniques.</p><p><i>MRI Physics: Tech to Tech Explanations</i> is designed to help student MRI technologists and radiotherapists preparing for Advanced MRI certification examinations to better understand difficult concepts and topics in a quick and easy manner.</p><p>Written by a highly experienced technologist, this useful guide provides clear and reader-friendly coverage of what every MR Technologist needs to know. Topics include safety considerations associated with the magnetic field and RF, pulse sequences, artifacts, MRI math, the much-feared gradients, and I.V. contrast.</p><ul><li>Provides basic guidance on safety considerations, protocols options, critical thinking, and image contrast optimization</li><li>Simplifies the challenging topic of MRI physics using straightforward language and clear explanations</li><li>Covers content for American Registry of Radiologic Technologists (ARRT) and Continuing Qualifications Requirements (CQR) exams</li><li>Features numerous illustrations and photographs of various MRI concepts, pulse sequence design, artifacts, and the application of concepts in clinical settings</li></ul><p><i>MRI Physics: Tech to Tech Explanations</i> is a must-have resource for the experienced and training MRI technologist, medical students, and radiology residency rotations.</p>

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