Photoacoustic imaging and spectroscopy
著者
書誌事項
Photoacoustic imaging and spectroscopy
(Optical science and engineering, 144)
CRC, c2009
大学図書館所蔵 全9件
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  島根
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  香川
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注記
Includes bibliographical references and index
内容説明・目次
内容説明
Photoacoustics promises to revolutionize medical imaging and may well make as dramatic a contribution to modern medicine as the discovery of the x-ray itself once did. Combining electromagnetic and ultrasonic waves synergistically, photoacoustics can provide deep speckle-free imaging with high electromagnetic contrast at high ultrasonic resolution and without any health risk. While photoacoustic imaging is probably the fastest growing biomedical imaging technology, this book is the first comprehensive volume in this emerging field covering both the physics and the remarkable noninvasive applications that are changing diagnostic medicine.
Bringing together the leading pioneers in this field to write about their own work, Photoacoustic Imaging and Spectroscopy is the first to provide a full account of the latest research and developing applications in the area of biomedical photoacoustics.
Photoacoustics can provide functional sensing of physiological parameters such as the oxygen saturation of hemoglobin. It can also provide high-contrast functional imaging of angiogenesis and hypermetabolism in tumors in vivo. Discussing these remarkable noninvasive applications and so much more, this reference is essential reading for all researchers in medical imaging and those clinicians working at the cutting-edge of modern biotechnology to develop diagnostic techniques that can save many lives and just as importantly do no harm.
目次
Half-time Image Reconstruction in Thermoacoustic Tomography. Two-dimensional Quantitative Photoacoustic Image Reconstruction of Adsorption Distributions in Scattering Media by Use of a Simple Iterative Method. Three-dimensional Photoacoustic Imaging of Blood Vessels in Tissue. Photoacoustic Monopole Radiation in One-Dimension, Two-Dimension, and Three-Dimension. Measurement of Blood Perfusion using Photoacoustic, Ultrasound, and Strain Imaging. Optoacoustic Monitoring of Blood Oxygenation. Determining a Function from its Mean Values over a Family of Spheres. Combined Ultrasound and Optoacoustic System for Real-time High-Contrast Vascular Imaging in Vivo. Time-Resolved Laser Optoacoustic Tomography of Inhomogeneous Media. Thermoacoustic Computed Tomography of Thick Biological Tissues. Image Reconstruction in Optoacoustic Tomography for Dispersive Acoustic Media. Universal Back-Projection Algorithm for Photoacoustic Tomography. Adaptive and Robust Techniques for Thermoacoustic Tomography. Photoacoustic Molecular Imaging. Virtual Detector-based Photoacoustic Microscopy. Quantitative Photoacoustic Sensing of Blood Oxygenation. High Frequency Optoacoustic Arrays using Etalon Detection. Optoacoustic Imaging of the Breast. Thermoacoustic Tomography with Integrating Area and Line Detectors. Thermoacoustic Tomography: Consistency Conditions and the Partial Scan Problem. Photoacoustic Determination of Blood Vessel Diameter. Photoacoustic Probe for Port Wine Stain Depth Determination. Boundary Conditions in Photoacoustic Tomography. Functional Photoacoustic Tomography of Small-Animal Brains. Fast Photoacoustic Imaging System Based on 320-element Linear Transducer Array. Analysis of Spatial Resolution in Photoacoustic Tomography. Reconstructions in Limited-view Thermoacoustic Tomography. Time Reversal in Photoacoustic Tomography. Photoacoustic Imaging of Gene Expression In Vivo. Dark-field Confocal Photoacoustic Microscopy.
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