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"Three Dimensional biomedical ultrasonic imaging is relatively in its infancy and many areas for application like tumor detection and identification, virtual surgery planning, among others are being explored. These techniques are expected to provide the medical community with improved diagnostic and analysis capabilities. In order to better understand the image capture and processing issues in these environments, it is necessary to design and implement a reference three dimensional image capture and processing system. In a research environment, the most optimal approach to designing such systems is to leverage existing two dimensional capture technologies and enhance their capabilities for three dimensional imaging. This thesis formulates and implements one approach to developing a three dimensional data acquisition and display system for ultrasonic imaging."--Abstract.
Synthesizes for basic scientists and medical practitioners in any discipline the fundamentals, principles, historical evolution, current methods, and practical applications of three-dimensional imaging in medicine and biology. Compares all the major approaches and their benefits and limitations, and discusses such elements as multimodal imaging, computers, processing and visualization, measurement, and interpretation. Highly illustrated, including over 50 color plates. Annotation copyright by Book News, Inc., Portland, OR
Research and development of ultrasonic tomography technology for three-dimensional imaging of internal rail flaws : modeling and simulation./
This volume provides an understanding of the technology and clinical uses of three-dimensional ultrasound. The aim of the text is to assist radiologists in asking the right questions in choosing the ultrasound equipment to buy for their hospitals. The authors explain volume imaging and volume sonography technology and current information on acquisition and display methods, visualization, and quantitative analysis. The advantages of different types of acquisition and display are discussed to assist radiologists in comparing different types of equipment.
The ability to visualize, non-invasively, human internal organs in their true from and shape has intrigued mankind for centuries. While the recent inventions of medical imaging modalities such as computerized tomography and magnetic resonance imaging have revolutionized radiology, the development of three-dimensional (3D) imaging has brought us closer to the age-old quest of non-invasive visualization. The ability to not only visualize but to manipulate and analyze 3D structures from captured multidimensional image data, is vital to a number of diagnostic and therapeutic applications. 3D Imaging in Medicine, Second Edition, unique in its contents, covers both the technical aspects and the actual medical applications of the process in a single source. The value of this technology is obvious. For example, three dimensional imaging allows a radiologist to accurately target the positioning and dosage of chemotherapy as well as to make more accurate diagnoses by showing more pathology; it allows the vascular surgeon to study the flow of blood through clogged arteries; it allows the orthopedist to find all the pieces of a compound fracture; and, it allows oncologists to perform less invasive biopsies. In fact, one of the most important uses of 3D Imaging is in computer-assisted surgery. For example, in cancer surgery, computer images show the surgeon the extent of the tumor so that only the diseased tissue is removed. In short, 3D imaging provides clinicians with information that saves time and money. 3D Imaging in Medicine, Second Edition provides a ready reference on the fundamental science of 3D imaging and its medical applications. The chapters have been written by experts in the field, and the technical aspects are covered in a tutorial fashion, describing the basic principles and algorithms in an easily understandable way. The application areas covered include: surgical planning, neuro-surgery, orthopedics, prosthesis design, brain imaging, analysis of cardio-pulmonary structures, and the assessment of clinical efficacy. The book is designed to provide a quick and systematic understanding of the principles of biomedical visualization to students, scientists and researchers, and to act as a source of information to medical practitioners on a wide variety of clinical applications of 3D imaging.