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Ultrasound Elastography for Biomedical Applications and Medicine

Ultrasound Elastography for Biomedical Applications and Medicine

9781119021513
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Description

Ultrasound Elastography for Biomedical Applications and Medicine

Ivan Z. Nenadic, Matthew W. Urban, James F. Greenleaf, Mayo Clinic Ultrasound Research Laboratory, Mayo Clinic College of Medicine, USA

Jean-Luc Gennisson, Miguel Bernal, Mickael Tanter, Institut Langevin – Ondes et Images, ESPCI ParisTech CNRS, France

Covers all major developments and techniques of Ultrasound Elastography and biomedical applications

The field of ultrasound elastography has developed various techniques with the potential to diagnose and track the progression of diseases such as breast and thyroid cancer, liver and kidney fibrosis, congestive heart failure, and atherosclerosis. Having emerged in the last decade, ultrasound elastography is a medical imaging modality that can noninvasively measure and map the elastic and viscous properties of soft tissues.

Ultrasound Elastography for Biomedical Applications and Medicine covers the basic physics of ultrasound wave propagation and the interaction of ultrasound with various media. The book introduces tissue elastography, covers the history of the field, details the various methods that have been developed by research groups across the world, and describes its novel applications, particularly in shear wave elastography.

Key features::

  • Covers all major developments and techniques of ultrasound elastography and biomedical applications.
  • Contributions from the pioneers of the field secure the most complete coverage of ultrasound elastography available.

The book is essential reading for researchers and engineers working in ultrasound and elastography, as well as biomedical engineering students and those working in the field of biomechanics.

Product Details
John Wiley and Sons
64613
9781119021513
9781119021513

Data sheet

Publication date
2019
Issue number
1
Cover
hard cover
Pages count
616
Dimensions (mm)
181.00 x 260.00
Weight (g)
1168

  • List of Contributors xix

    Section I Introduction 1

    1 Editors’ Introduction 3
    Ivan Nenadic, Matthew Urban, James Greenleaf, Jean-Luc Gennisson,Miguel Bernal, and Mickael Tanter

    References 5

    Section II Fundamentals of Ultrasound Elastography 7

    2 Theory of Ultrasound Physics and Imaging 9
    Roberto Lavarello andMichael L. Oelze

    2.1 Introduction 9

    2.2 Modeling the Response of the Source to Stimuli [h(t)] 10

    2.3 Modeling the Fields from Sources [p(t, x)] 12

    2.4 Modeling an Ultrasonic Scattered Field [s(t, x)] 15

    2.5 Modeling the Bulk Properties of the Medium [a(t, x)] 19

    2.6 Processing Approaches Derived from the Physics of Ultrasound [?] 21

    2.7 Conclusions 26

    References 27

    3 Elastography and the Continuum of Tissue Response 29
    Kevin J. Parker

    3.1 Introduction 29

    3.2 Some Classical Solutions 31

    3.3 The Continuum Approach 32

    3.4 Conclusion 33

    Acknowledgments 33

    References 34

    4 Ultrasonic Methods for Assessment of TissueMotion in Elastography 35
    Jingfeng Jiang and Bo Peng

    4.1 Introduction 35

    4.2 Basic Concepts and their Relevance in Tissue Motion Tracking 36

    4.3 Tracking Tissue Motion through Frequency-domain Methods 37

    4.4 Maximum Likelihood (ML) Time-domain Correlation-based Methods 39

    4.5 Tracking Tissue Motion through Combining Time-domain and Frequency-domain Information 44

    4.6 Time-domain Maximum A Posterior (MAP) Speckle Tracking Methods 45

    4.7 Optical Flow-based Tissue Motion Tracking 53

    4.8 Deformable Mesh-based Motion-tracking Methods 55

    4.9 Future Outlook 57

    4.10 Conclusions 63

    Acknowledgments 63

    Acronyms 63

    Additional Nomenclature of Definitions and Acronyms 64

    References 65

    Section III Theory of Mechanical Properties of Tissue 71

    5 Continuum Mechanics Tensor Calculus and Solutions toWave Equations 73
    Luiz Vasconcelos, Jean-Luc Gennisson, and Ivan Nenadic

    5.1 Introduction 73

    5.2 Mathematical Basis and Notation 73

    5.3 Solutions toWave Equations 75

    References 81

    6 TransverseWave Propagation in Anisotropic Media 82
    Jean-Luc Gennisson

    6.1 Introduction 82

    6.2 Theoretical Considerations from General to Transverse Isotropic Models for Soft Tissues 82

    6.3 Experimental Assessment of Anisotropic Ratio by ShearWave Elastography 87

    6.4 Conclusion 88

    References 88

    7 TransverseWave Propagation in Bounded Media 90
    Javier Brum

    7.1 Introduction 90

    7.2 TransverseWave Propagation in Isotropic Elastic Plates 90

    7.3 Plate in Vacuum: LambWaves 93

    7.4 Viscoelastic Plate in Liquid: Leaky LambWaves 96

    7.5 Isotropic Plate Embedded Between Two Semi-infinite Elastic Solids 99

    7.6 TransverseWave Propagation in Anisotropic Viscoelastic Plates Surrounded by Non-viscous Fluid 100

    7.7 Conclusions 103

    Acknowledgments 103

    References 103

    8 Rheological Model-based Methods for Estimating Tissue Viscoelasticity 105
    Jean-Luc Gennisson

    8.1 Introduction 105

    8.2 Shear Modulus and Rheological Models 106

    8.3 Applications of Rheological Models 113

    References 116

    9 Wave Propagation in ViscoelasticMaterials 118
    YueWang andMichael F. Insana

    9.1 Introduction 118

    9.2 Estimating the Complex Shear Modulus from PropagatingWaves 119

    9.3 Wave Generation and Propagation 120

    9.4 Rheological Models 122

    9.5 Experimental Results and Applications 124

    9.6 Summary 125

    References 126

    Section IV Static and Low Frequency Elastography 129

    10 Validation of Quantitative Linear and Nonlinear Compression Elastography 131
    Jean Francois Dord, Sevan Goenezen, Assad A. Oberai, Paul E. Barbone, Jingfeng Jiang,Timothy J. Hall, and Theo Pavan

    10.1 Introduction 131

    10.2 Methods 132

    10.3 Results 134

    10.4 Discussion 137

    10.5 Conclusions 140

    Acknowledgement 141

    References 141

    11 Cardiac Strain and Strain Rate Imaging 143
    Brecht Heyde, OanaMirea, and Jan D’hooge

    11.1 Introduction 143

    11.2 Strain Definitions in Cardiology 143

    11.3 Methodologies Towards Cardiac Strain (Rate) Estimation 145

    11.4 Experimental Validation of the Proposed Methodologies 149

    11.4.1 Synthetic Data Testing 150

    11.5 Clinical Applications 151

    11.6 Future Developments 153

    References 154

    12 Vascular and Intravascular Elastography 161
    Marvin M. Doyley

    12.1 Introduction 161

    12.2 General Principles 161

    12.3 Conclusion 168

    References 168

    13 Viscoelastic Creep Imaging 171
    Carolina Amador Carrascal

    13.1 Introduction 171

    13.2 Overview of Governing Principles 172

    13.3 Imaging Techniques 173

    13.4 Conclusion 187

    References 187

    14 Intrinsic CardiovascularWave and Strain Imaging 189
    Elisa Konofagou

    14.1 Introduction 189

    14.2 Cardiac Imaging 189

    14.3 Vascular Imaging 208

    Acknowledgements 219

    References 219

    Section V Harmonic ElastographyMethods 227

    15 Dynamic Elasticity Imaging 229
    Kevin J. Parker

    15.1 Vibration Amplitude Sonoelastography: Early Results 229

    15.2 Sonoelastic Theory 229

    15.3 Vibration Phase Gradient Sonoelastography 232

    15.4 CrawlingWaves 233

    15.5 Clinical Results 233

    15.6 Conclusion 234

    Acknowledgments 235

    References 235

    16 Harmonic ShearWave Elastography 238
    Heng Zhao

    16.1 Introduction 238

    16.2 Basic Principles 239

    16.3 Ex Vivo Validation 242

    16.4 In Vivo Application 244

    16.5 Summary 246

    Acknowledgments 247

    References 247

    17 Vibro-acoustography and its Medical Applications 250
    Azra Alizad andMostafa Fatemi

    17.1 Introduction 250

    17.2 Background 250

    17.3 Application of Vibro-acoustography for Detection of Calcifications 251

    17.4 In Vivo Breast Vibro-acoustography 254

    17.5 In VivoThyroid Vibro-acoustography 259

    17.6 Limitations and Further Future Plans 260

    Acknowledgments 261

    References 261

    18 Harmonic Motion Imaging 264
    Elisa Konofagou

    18.1 Introduction 264

    18.2 Background 264

    18.3 Methods 267

    18.4 Preclinical Studies 273

    18.5 Future Prospects 277

    Acknowledgements 279

    References 279

    19 ShearWave Dispersion Ultrasound Vibrometry 284
    Pengfei Song and Shigao Chen

    19.1 Introduction 284

    19.2 Principles of ShearWave Dispersion Ultrasound Vibrometry (SDUV) 284

    19.3 Clinical Applications 286

    19.4 Summary 291

    References 292

    Section VI Transient ElastographyMethods 295

    20 Transient Elastography: From Research to Noninvasive Assessment of Liver Fibrosis Using Fibroscan® 297
    Laurent Sandrin,Magali Sasso, Stéphane Audiere, Cécile Bastard, Céline Fournier,Jennifer Oudry, Véronique Miette, and Stefan Catheline

    20.1 Introduction 297

    20.2 Principles of Transient Elastography 297

    20.3 Fibroscan 301

    20.4 Application of Vibration-controlled Transient Elastography to Liver Diseases 306

    20.5 Other Applications of Transient Elastography 309

    20.6 Conclusion 310

    References 311

    21 From Time Reversal to Natural ShearWave Imaging 318
    Stefan Catheline

    21.1 Introduction: Time Reversal ShearWave in Soft Solids 318

    21.2 ShearWave Elastography using Correlation: Principle and Simulation Results 320

    21.3 Experimental Validation in Controlled Media 323

    21.4 Natural ShearWave Elastography: First In Vivo Results in the Liver, theThyroid, and the Brain 328

    21.5 Conclusion 331

    References 331

    22 Acoustic Radiation Force Impulse Ultrasound 334
    Tomasz J. Czernuszewicz and Caterina M. Gallippi

    22.1 Introduction 334

    22.2 Impulsive Acoustic Radiation Force 334

    22.3 Monitoring ARFI-induced Tissue Motion 335

    22.4 ARFI Data Acquisition 340

    22.5 ARFI Image Formation 341

    22.6 Real-time ARFI Imaging 343

    22.7 Quantitative ARFI Imaging 345

    22.8 ARFI Imaging in Clinical Applications 346

    22.9 Commercial Implementation 350

    22.10 Related Technologies 350

    22.11 Conclusions 351

    References 351

    23 Supersonic Shear Imaging 357
    Jean-Luc Gennisson andMickael Tanter

    23.1 Introduction 357

    23.2 Radiation Force Excitation 357

    23.3 Ultrafast Imaging 362

    23.4 ShearWave Speed Mapping 364

    23.5 Conclusion 365

    References 366

    24 Single Tracking Location ShearWave Elastography 368
    Stephen A.McAleavey

    24.1 Introduction 368

    24.2 SMURF 370

    24.3 STL-SWEI 373

    24.4 Noise in SWE/Speckle Bias 376

    24.5 Estimation of viscoelastic parameters (STL-VE) 380

    24.6 Conclusion 384

    References 384

    25 Comb-push Ultrasound Shear Elastography 388
    Pengfei Song and Shigao Chen

    25.1 Introduction 388

    25.2 Principles of Comb-push Ultrasound Shear Elastography (CUSE) 389

    25.3 Clinical Applications of CUSE 396

    25.4 Summary 396

    References 397

    Section VII Emerging Research Areas in Ultrasound Elastography 399

    26 Anisotropic ShearWave Elastography 401
    Sara Aristizabal

    26.1 Introduction 401

    26.2 ShearWave Propagation in Anisotropic Media 402

    26.3 Anisotropic ShearWave Elastography Applications 403

    26.4 Conclusion 420

    References 420

    27 Application of GuidedWaves for Quantifying Elasticity and Viscoelasticity of Boundary Sensitive Organs 422
    Sara Aristizabal, Matthew Urban, Luiz Vasconcelos, BenjaminWood,Miguel Bernal,Javier Brum, and Ivan Nenadic

    27.1 Introduction 422

    27.2 Myocardium 422

    27.3 Arteries 426

    27.4 Urinary Bladder 431

    27.5 Cornea 433

    27.6 Tendons 435

    27.7 Conclusions 439

    References 439

    28 Model-free Techniques for Estimating Tissue Viscoelasticity 442
    Daniel Escobar, Luiz Vasconcelos, Carolina Amador Carrascal, and Ivan Nenadic

    28.1 Introduction 442

    28.2 Overview of Governing Principles 442

    28.3 Imaging Techniques 443

    28.4 Conclusion 449

    References 449

    29 Nonlinear Shear Elasticity 451
    Jean-Luc Gennisson and Sara Aristizabal

    29.1 Introduction 451

    29.2 Shocked Plane ShearWaves 451

    29.3 Nonlinear Interaction of Plane ShearWaves 455

    29.4 Acoustoelasticity Theory 460

    29.5 Assessment of 4th Order Nonlinear Shear Parameter 465

    29.6 Conclusion 468

    References 468

    Section VIII Clinical Elastography Applications 471

    30 Current and Future Clinical Applications of Elasticity Imaging Techniques 473
    Matthew Urban

    30.1 Introduction 473

    30.2 Clinical Implementation and Use of Elastography 474

    30.3 Clinical Applications 475

    30.3.1 Liver 475

    30.3.2 Breast 476

    30.3.3 Thyroid 476

    30.3.4 Musculoskeletal 476

    30.3.5 Kidney 477

    30.3.6 Heart 478

    30.3.7 Arteries and Atherosclerotic Plaques 479

    30.4 FutureWork in Clinical Applications of Elastography 480

    30.5 Conclusions 480

    Acknowledgments 480

    References 481

    31 Abdominal Applications of ShearWave Ultrasound Vibrometry and Supersonic Shear Imaging 492
    Pengfei Song and Shigao Chen

    31.1 Introduction 492

    31.2 Liver Application 492

    31.3 Prostate Application 494

    31.4 Kidney Application 495

    31.5 Intestine Application 496

    31.6 Uterine Cervix Application 497

    31.7 Spleen Application 497

    31.8 Pancreas Application 497

    31.9 Bladder Application 498

    31.10 Summary 499

    References 499

    32 Acoustic Radiation Force-based Ultrasound Elastography for Cardiac Imaging Applications 504
    Stephanie A. Eyerly-Webb,MaryamVejdani-Jahromi, Vaibhav Kakkad, Peter Hollender,David Bradway, andGregg Trahey

    32.1 Introduction 504

    32.2 Acoustic Radiation Force-based Elastography Techniques 504

    32.3 ARF-based Elasticity Assessment of Cardiac Function 505

    32.4 ARF-based Image Guidance for Cardiac Radiofrequency Ablation Procedures 510

    32.5 Conclusions 515

    Funding Acknowledgements 515

    References 516

    33 Cardiovascular Application of ShearWave Elastography 520
    Pengfei Song and Shigao Chen

    33.1 Introduction 520

    33.2 Cardiovascular ShearWave Imaging Techniques 521

    33.3 Clinical Applications of Cardiovascular ShearWave Elastography 525

    33.4 Summary 529

    References 530

    34 Musculoskeletal Applications of Supersonic Shear Imaging 534
    Jean-Luc Gennisson

    34.1 Introduction 534

    34.2 Muscle Stiffness at Rest and During Passive Stretching 535

    34.3 Active and Dynamic Muscle Stiffness 537

    34.4 Tendon Applications 539

    34.5 Clinical Applications 541

    34.6 Future Directions 542

    References 542

    35 Breast ShearWave Elastography 545
    Azra Alizad

    35.1 Introduction 545

    35.2 Background 545

    35.3 Breast Elastography Techniques 546

    35.4 Application of CUSE for Breast Cancer Detection 548

    35.5 CUSE on a Clinical Ultrasound Scanner 549

    35.6 Limitations of Breast ShearWave Elastography 551

    35.7 Conclusion 552

    Acknowledgments 552

    References 552

    36 Thyroid ShearWave Elastography 557
    Azra Alizad

    36.1 Introduction 557

    36.2 Background 557

    36.3 Role of Ultrasound and its Limitation inThyroid Cancer Detection 557

    36.4 Fine Needle Aspiration Biopsy (FNAB) 558

    36.5 The Role of Elasticity Imaging 558

    36.6 Application of CUSE onThyroid 561

    36.7 CUSE on Clinical Ultrasound Scanner 561

    36.8 Conclusion 563

    Acknowledgments 564

    References 564

    Section IX Perspective on Ultrasound Elastography 567

    37 Historical Growth of Ultrasound Elastography and Directions for the Future 569
    Armen Sarvazyan andMatthewW. Urban

    37.1 Introduction 569

    37.2 Elastography Publication Analysis 569

    37.3 Future Investigations of Acoustic Radiation Force for Elastography 574

    37.3.1 Nondissipative Acoustic Radiation Force 574

    37.3.2 Nonlinear Enhancement of Acoustic Radiation Force 575

    37.3.3 SpatialModulation of Acoustic Radiation Force Push Beams 575

    37.4 Conclusions 576

    Acknowledgments 577

    References 577

    Index 581

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