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Ultrasound Elastography for Biomedical Applications and Medicine.
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 Paris...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Otros Autores: | , , , , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Newark :
John Wiley & Sons, Incorporated,
2018.
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| Temas: | |
| Acceso en línea: | Texto completo |
MARC
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| 100 | 1 | |a Nenadic, Ivan Z. | |
| 245 | 1 | 0 | |a Ultrasound Elastography for Biomedical Applications and Medicine. |
| 260 | |a Newark : |b John Wiley & Sons, Incorporated, |c 2018. | ||
| 300 | |a 1 online resource (616 pages) | ||
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| 505 | 8 | |6 880-01 |a Chapter 3 Elastography and the Continuum of Tissue Response3.1 Introduction; 3.2 Some Classical Solutions; 3.3 The Continuum Approach; 3.4 Conclusion; Acknowledgments; References; Chapter 4 Ultrasonic Methods for Assessment of Tissue Motion in Elastography; 4.1 Introduction; 4.2 Basic Concepts and their Relevance in Tissue Motion Tracking; 4.2.1 Ultrasound Signal Processing; 4.2.2 Constitutive Modeling of Soft Tissues; 4.3 Tracking Tissue Motion through Frequency-domain Methods; 4.4 Maximum Likelihood (ML) Time-domain Correlation-based Methods. | |
| 505 | 8 | |a 4.5 Tracking Tissue Motion through Combining Time-domain and Frequency-domain Information4.6 Time-domain Maximum A Posterior (MAP) Speckle Tracking Methods; 4.6.1 Tracking Large Tissue Motion; 4.6.2 Strategies for Accurately Tracking Large Tissue Motion; 4.6.2.1 Maximize Prior Information; 4.6.2.2 Regularized Motion Tracking Using Smoothness Constraint(s); 4.6.2.3 Bayesian Speckle Tracking; 4.6.3 Discussions; 4.7 Optical Flow-based Tissue Motion Tracking; 4.7.1 Region-based Optical Flow Methods; 4.7.2 Optical Flow Methods with Smoothness Constraints. | |
| 505 | 8 | |a 4.8 Deformable Mesh-based Motion-tracking Methods4.9 Future Outlook; 4.9.1 Tracking Lateral Tissue Motion; 4.9.2 Tracking Large Tissue Motion; 4.9.3 Testing of Motion-tracking Algorithms; 4.9.3.1 Evaluation of Performance; 4.9.3.2 Testing Data; 4.9.4 Future with Volumetric Ultrasound Data; 4.10 Conclusions; Acknowledgments; Acronyms; Additional Nomenclature of Definitions and Acronyms; References; Section III Theory of Mechanical Properties of Tissue; Chapter 5 Continuum Mechanics Tensor Calculus and Solutions to Wave Equations; 5.1 Introduction; 5.2 Mathematical Basis and Notation. | |
| 505 | 8 | |a 5.2.1 Tensor Notation5.2.2 Vector Operators; 5.2.3 Important Tensors and Notations; 5.3 Solutions to Wave Equations; 5.3.1 Displacement and Deformation; 5.3.2 The Stress Tensor; 5.3.3 Stress-Strain Relation; 5.3.4 Displacement Equation of Motion; 5.3.5 Helmholtz Decomposition; 5.3.6 Compressional and Shear Waves; References; Chapter 6 Transverse Wave Propagation in Anisotropic Media; 6.1 Introduction; 6.2 Theoretical Considerations from General to Transverse Isotropic Models for Soft Tissues; 6.3 Experimental Assessment of Anisotropic Ratio by Shear Wave Elastography. | |
| 500 | |a 6.3.1 Transient Elastography. | ||
| 520 | |a 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. | ||
| 590 | |a ProQuest Ebook Central |b Ebook Central Academic Complete | ||
| 650 | 7 | |a TECHNOLOGY & ENGINEERING |x Mechanical. |2 bisacsh | |
| 700 | 1 | |a Urban, Matthew W. | |
| 700 | 1 | |a Gennisson, Jean-Luc. | |
| 700 | 1 | |a Bernal, Miguel. | |
| 700 | 1 | |a Tanter, Mikael. | |
| 700 | 1 | |a Greenleaf, James F. | |
| 758 | |i has work: |a Ultrasound elastography for biomedical applications and medicine (Text) |1 https://id.oclc.org/worldcat/entity/E39PCGhVkR9xYGw7tm8x8QBYxC |4 https://id.oclc.org/worldcat/ontology/hasWork | ||
| 776 | 0 | 8 | |i Print version: |a Nenadic, Ivan Z. |t Ultrasound Elastography for Biomedical Applications and Medicine. |d Newark : John Wiley & Sons, Incorporated, ©2018 |z 9781119021513 |
| 856 | 4 | 0 | |u https://ebookcentral.uam.elogim.com/lib/uam-ebooks/detail.action?docID=5568367 |z Texto completo |
| 880 | 0 | |6 505-01/(S |a Cover; Title Page; Copyright; Contents; List of Contributors; Section I Introduction; Chapter 1 Editors' Introduction; References; Section II Fundamentals of Ultrasound Elastography; Chapter 2 Theory of Ultrasound Physics and Imaging; 2.1 Introduction; 2.2 Modeling the Response of the Source to Stimuli [h(t)]; 2.3 Modeling the Fields from Sources [p(t, x)]; 2.4 Modeling an Ultrasonic Scattered Field [s(t, x)]; 2.5 Modeling the Bulk Properties of the Medium [a(t, x)]; 2.6 Processing Approaches Derived from the Physics of Ultrasound [Ω]; 2.7 Conclusions; References. | |
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