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Author: José Fernando Zvietcovich Zegarra Publisher: ISBN: Category : Languages : en Pages : 221
Book Description
"Dynamic optical coherence elastography (OCE) is a functional imaging modality which leverages the propagation of mechanical waves in order to estimate the mechanical properties of tissues. It is very useful since it does not require (i) a priori knowledge of force/stress, (ii) mandatory direct contact between the mechanical loading source and the tissue under study, and (iii) large deformation of tissues. Therefore, dynamic OCE shows promise for non-contact, in situ, and in vivo mechanical characterization of tissues with applications in laboratory and clinical studies. To date, the impact of using transient/continuous temporal excitation produced by one/multiple loading sources on the effectiveness of OCE methods for the elastic characterization of tissues has not been fully explored. Further, due to the small field of view of optical coherence tomography (OCT) (~ 2 mm along depth), the complexity of boundary conditions of tissues (such as heterogeneous, composite, or plate-shaped media), and the excitation wavelength (typically between 0.1 mm 10 mm), surface acoustic waves (SAW) are the dominant perturbation. These diminish the capability of OCE methods to estimate depth-dependent tissue elasticity information (such as in layered or composite materials). Moreover, the estimation of viscous parameters in addition to the classic elastic modulus is of great interest since it can provide useful information of disease stages. However, most OCE methods assume a rheological model of tissues and utilize only frequency-dependent wave speed measurements, disregarding valuable information given by the wave attenuation process. Finally, the exploration of novel dynamic OCE techniques to address the aforementioned issues, including the aberration of waves in heterogeneous and anisotropic media and the multiple wave reflections produced by irregular boundary conditions, is highly desired. In this thesis, a comparative study of transient and continuous dynamic OCE methods and estimators when using one or two vibration sources is conducted. Resolution, accuracy error, precision error, and contrast-to-noise ratio are the selected metrics for evaluating the performance of each method in numerical simulations and experiments in tissue-mimicking phantoms. Furthermore, a novel OCE method based on reverberant shear wave fields in elastic media is presented. This method arose as a response to the limitations found in the comparative study developed previously. Numerical simulations and experiments in ex vivo porcine cornea demonstrate the capabilities of the proposed technique for layered material elastic characterization compared to SAW-based OCE methods. Subsequently, a novel technique for the viscoelastic characterization of tissues by propagating Gaussian-shape transient waves using acoustic radiation force (ARF) excitation is developed. Experimental results in viscoelastic tissue-mimicking phantoms validated the proposed approach, accounting for dispersion, distortion, and attenuation of transient waves while not assuming any rheological model for tissue characterization. In addition, a study on longitudinal shear waves generated using a disk-shaped glass plate for the elastic characterization of heterogeneous distributed media is presented. Numerical simulations and experiments in tissue-mimicking phantoms demonstrate the capabilities and difficulties of such waves in detecting vertically and horizontally distributed materials. Preliminary experiments in mouse brain tissue are conducted followed by a discussion on future implementations of this method for in vivo mouse brain elastography studies. Finally, the elastography of small substructures in rabbit cornea produced by localized laser-induced refractive index change (LIRIC treatment) using OCE techniques is explored. In addition, the study of anisotropic tissues (chicken tibialis muscle and porcine brain) using non-contact ARF excitation is conducted. In these studies, a transverse isotropic mechanical model is used and validated. In summary, we have (i) conducted a series of studies using numerical simulations and tissue-mimicking phantoms to understand the nature, properties, and capabilities of mechanical waves for the elastography of tissues; (ii) developed a set of novel dynamic OCE approaches that are capable of detecting subtle changes (>13% change in elastic properties) within tissues, and with a spatial resolution as low as 120 um along lateral axis and 55.5 um along depth axis; and (iii) applied these approaches to the study of tissues with different boundary conditions (composite plate-shaped media such as cornea, mouse in situ brain tissue, etc.) and diverse mechanical properties (viscoelastic, heterogeneous, and anisotropic tissues)"--Pages xviii-xxi.
Author: José Fernando Zvietcovich Zegarra Publisher: ISBN: Category : Languages : en Pages : 221
Book Description
"Dynamic optical coherence elastography (OCE) is a functional imaging modality which leverages the propagation of mechanical waves in order to estimate the mechanical properties of tissues. It is very useful since it does not require (i) a priori knowledge of force/stress, (ii) mandatory direct contact between the mechanical loading source and the tissue under study, and (iii) large deformation of tissues. Therefore, dynamic OCE shows promise for non-contact, in situ, and in vivo mechanical characterization of tissues with applications in laboratory and clinical studies. To date, the impact of using transient/continuous temporal excitation produced by one/multiple loading sources on the effectiveness of OCE methods for the elastic characterization of tissues has not been fully explored. Further, due to the small field of view of optical coherence tomography (OCT) (~ 2 mm along depth), the complexity of boundary conditions of tissues (such as heterogeneous, composite, or plate-shaped media), and the excitation wavelength (typically between 0.1 mm 10 mm), surface acoustic waves (SAW) are the dominant perturbation. These diminish the capability of OCE methods to estimate depth-dependent tissue elasticity information (such as in layered or composite materials). Moreover, the estimation of viscous parameters in addition to the classic elastic modulus is of great interest since it can provide useful information of disease stages. However, most OCE methods assume a rheological model of tissues and utilize only frequency-dependent wave speed measurements, disregarding valuable information given by the wave attenuation process. Finally, the exploration of novel dynamic OCE techniques to address the aforementioned issues, including the aberration of waves in heterogeneous and anisotropic media and the multiple wave reflections produced by irregular boundary conditions, is highly desired. In this thesis, a comparative study of transient and continuous dynamic OCE methods and estimators when using one or two vibration sources is conducted. Resolution, accuracy error, precision error, and contrast-to-noise ratio are the selected metrics for evaluating the performance of each method in numerical simulations and experiments in tissue-mimicking phantoms. Furthermore, a novel OCE method based on reverberant shear wave fields in elastic media is presented. This method arose as a response to the limitations found in the comparative study developed previously. Numerical simulations and experiments in ex vivo porcine cornea demonstrate the capabilities of the proposed technique for layered material elastic characterization compared to SAW-based OCE methods. Subsequently, a novel technique for the viscoelastic characterization of tissues by propagating Gaussian-shape transient waves using acoustic radiation force (ARF) excitation is developed. Experimental results in viscoelastic tissue-mimicking phantoms validated the proposed approach, accounting for dispersion, distortion, and attenuation of transient waves while not assuming any rheological model for tissue characterization. In addition, a study on longitudinal shear waves generated using a disk-shaped glass plate for the elastic characterization of heterogeneous distributed media is presented. Numerical simulations and experiments in tissue-mimicking phantoms demonstrate the capabilities and difficulties of such waves in detecting vertically and horizontally distributed materials. Preliminary experiments in mouse brain tissue are conducted followed by a discussion on future implementations of this method for in vivo mouse brain elastography studies. Finally, the elastography of small substructures in rabbit cornea produced by localized laser-induced refractive index change (LIRIC treatment) using OCE techniques is explored. In addition, the study of anisotropic tissues (chicken tibialis muscle and porcine brain) using non-contact ARF excitation is conducted. In these studies, a transverse isotropic mechanical model is used and validated. In summary, we have (i) conducted a series of studies using numerical simulations and tissue-mimicking phantoms to understand the nature, properties, and capabilities of mechanical waves for the elastography of tissues; (ii) developed a set of novel dynamic OCE approaches that are capable of detecting subtle changes (>13% change in elastic properties) within tissues, and with a spatial resolution as low as 120 um along lateral axis and 55.5 um along depth axis; and (iii) applied these approaches to the study of tissues with different boundary conditions (composite plate-shaped media such as cornea, mouse in situ brain tissue, etc.) and diverse mechanical properties (viscoelastic, heterogeneous, and anisotropic tissues)"--Pages xviii-xxi.
Author: Wenjuan Qi Publisher: ISBN: 9781303612725 Category : Languages : en Pages : 129
Book Description
Optical coherence tomography (OCT) is a noninvasive, high resolution and high speed imaging modality that provides cross-sectional depth resolved microstructure information of biological tissues based on their tissue scattering properties. However, subtle scattering property changes in diseased tissue are difficult to visualize solely by OCT structural imaging at the early stages of disease. Elastography has opened new horizons for medical imaging by characterizing the mechanical properties of biological tissues. However, current elastography imaging modalities such as ultrasound (US) elastography and magnetic resonant elastography (MRE) can only image mechanical properties at the organ level due to their limitations in resolution. Although current optical coherence elastography (OCE) technologies can achieve microscale imaging of tissue mechanical properties, they are still facing challenges for real time in vivo imaging. My Ph.D. research focuses on the development of a novel phase-resolved acoustic radiation force optical coherence elastography technology (ARF-OCE). This technique combines the dynamic acoustic radiation force (ARF) excitation with phase-resolved OCT to achieve high resolution, high speed and high sensitivity for imaging and characterizing tissue biomechanical properties. The ARF-OCE technique uses a localized amplitude modulated (AM) acoustic wave to apply dynamic "pushes" on the sample and phase-resolved OCT to evaluate the ARF-induced displacement of the sample by determining the phase shift of OCT interference fringe. Three generations of ARF-OCE configurations have been developed as a consequence of system optimization. The first generation ARF-OCE system utilizes a focused ultrasonic transducer and stimulates the object in "transmission" mode. Aiming for in vivo imaging, the second generation ARF-OCE system features a confocal OCT and ARF arrangement and a "reflection" excitation mode. A dual-element ring transducer is used for the third generation ARF-OCE system that makes use of the "beat" phenomenon in order to achieve highly localized ARF excitation. Imaging results from both tissue phantoms and ex vivo real tissue specimens have demonstrated the feasibility of the phase-resolved ARF-OCE technique for tissue elasticity imaging with superior performance. Finally, a frequency-dependent resonant ARF-OCE method has also been developed to characterize tissue biomechanical properties using the resonant frequency without the knowledge of ARF parameters.
Author: Michael Pircher Publisher: MDPI ISBN: 3038427446 Category : Computers Languages : en Pages : 213
Book Description
This book is a printed edition of the Special Issue "Development and Application of Optical Coherence Tomography (OCT)" that was published in Applied Sciences
Author: S. Kaisar Alam Publisher: Elsevier ISBN: 0128096837 Category : Science Languages : en Pages : 260
Book Description
Tissue Elasticity Imaging: Volume One: Theory and Methods offers an extensive treatment of the fundamentals and applications of this groundbreaking diagnostic modality. The book introduces elasticity imaging, its history, the fundamental physics, and the different elasticity imaging methods, along with their implementation details, problems and artefacts. It is an essential resource for all researchers and practitioners interested in any elasticity imaging modality. As many diseases, including cancers, alter tissue mechanical properties, it is not always possible for conventional methods to detect changes, but with elasticity images that are produced by slow tissue deformation or low-frequency vibration, these changes can be displayed. Offers the first comprehensive reference on elasticity imaging Discusses the fundamentals of technology and their limitations and solutions, along with advanced methods and future directions Addresses the technologies and applications useful to both researchers and clinical practitioners Includes an online reference section regularly updated with advances in technology and applications
Author: Ruikang K. Wang Publisher: Taylor & Francis ISBN: 1439895821 Category : Science Languages : en Pages : 726
Book Description
Despite a number of books on biophotonics imaging for medical diagnostics and therapy, the field still lacks a comprehensive imaging book that describes state-of-the-art biophotonics imaging approaches intensively developed in recent years. Addressing this shortfall, Advanced Biophotonics: Tissue Optical Sectioning presents contemporary methods and
Author: Wolfgang Drexler Publisher: Springer Science & Business Media ISBN: 3540775501 Category : Medical Languages : en Pages : 1346
Book Description
Optical coherence tomography (OCT) is the optical analog of ultrasound imaging and is emerging as a powerful imaging technique that enables non-invasive, in vivo, high resolution, cross-sectional imaging in biological tissue. This book introduces OCT technology and applications not only from an optical and technological viewpoint, but also from biomedical and clinical perspectives. The chapters are written by leading research groups, in a style comprehensible to a broad audience.
Author: S. Kaisar Alam Publisher: Elsevier ISBN: 0128096616 Category : Science Languages : en Pages : 258
Book Description
Tissue Elasticity Imaging: Volume One, Theory and Methods offers an extensive treatment of the fundamentals and applications of this groundbreaking diagnostic modality. The book introduces elasticity imaging, its history, the fundamental physics, and the different elasticity imaging methods, along with their implementation details, problems and artefacts. It is an essential resource for all researchers and practitioners interested in any elasticity imaging modality. As many diseases, including cancers, alter tissue mechanical properties, it is not always possible for conventional methods to detect changes, but with elasticity images that are produced by slow tissue deformation or low-frequency vibration, these changes can be displayed. Offers the first comprehensive reference on elasticity imaging Discusses the fundamentals of technology and their limitations and solutions, along with advanced methods and future directions Addresses the technologies and applications useful to both researchers and clinical practitioners Includes an online reference section regularly updated with advances in technology and applications
Author: Sudhakar K. Venkatesh Publisher: Springer ISBN: 1493915754 Category : Medical Languages : en Pages : 143
Book Description
The first book to cover the groundbreaking development and clinical applications of Magnetic Resonance Elastography, this book is essential for all practitioners interested in this revolutionary diagnostic modality. The book is divided into three sections. The first covers the history of MRE. The second covers technique and clinical applications of MRE in the liver with respect to fibrosis, liver masses, and other diseases. Case descriptions are presented to give the reader a hands-on approach. The final section presents the techniques, sequence and preliminary results of applications in other areas of the body including muscle, brain, lung, heart, and breast.
Author: Josef F. Bille Publisher: Springer ISBN: 3030166384 Category : Medical Languages : en Pages : 407
Book Description
This open access book provides a comprehensive overview of the application of the newest laser and microscope/ophthalmoscope technology in the field of high resolution imaging in microscopy and ophthalmology. Starting by describing High-Resolution 3D Light Microscopy with STED and RESOLFT, the book goes on to cover retinal and anterior segment imaging and image-guided treatment and also discusses the development of adaptive optics in vision science and ophthalmology. Using an interdisciplinary approach, the reader will learn about the latest developments and most up to date technology in the field and how these translate to a medical setting. High Resolution Imaging in Microscopy and Ophthalmology – New Frontiers in Biomedical Optics has been written by leading experts in the field and offers insights on engineering, biology, and medicine, thus being a valuable addition for scientists, engineers, and clinicians with technical and medical interest who would like to understand the equipment, the applications and the medical/biological background. Lastly, this book is dedicated to the memory of Dr. Gerhard Zinser, co-founder of Heidelberg Engineering GmbH, a scientist, a husband, a brother, a colleague, and a friend.
Author: José Fernando Zvietcovich Zegarra
Author: José Fernando Zvietcovich Zegarra
Author: Srilatha Vantipalli
Author: Wenjuan Qi
Author: Michael Pircher
Author: S. Kaisar Alam
Author: Ruikang K. Wang
Author: Wolfgang Drexler
Author: S. Kaisar Alam
Author: Sudhakar K. Venkatesh
Author: Josef F. Bille