Digital image processing in medicine : proceedings, Hamburg, October 5, 1981

In diagnostic medicine a large part of information about the patient is drawn from data, which, more or less, are represented in an opti calor pictorial form. There is a very wide range of such data as e.g. the patients appearance, the various kinds of radiological images, or cytological imagery. In conventional diagnostics the data, as it comes from the acquisition device, is perceived by the physician and is interpreted with the help of a large amount of "a priori" knowledge to give a diagnostic finding. During the last 15 years a steadily rising number of attempts have been made to support these processes by the application of com puters. The attempts mainly concentrate on three objectives: 1. Support of the perception process by the production of better or new types of images, e.g. by Computer tomography or Computer angio graphy (image processing) . 2. Automation of the interpretation process, e.g. for bloodcell dif ferentiation (pattern recognition) . 3. Management of the steeply rising amount of medical image data in the hospital (image data bases) . Although the early applications of digital methods aimed at the second . . objective, in the last years much more success has been a achieved in the support of the perception process by methods of image process ing. The reason for this is obvious - in the case of automatic interpre tation the a priori knowledge of the physician has to be formalized.

Digital cardiovascular Radiology Medical motivations and technical developments.- The processing and analysis of radiographic image sequences.- 1. Introduction.- 2. Principles and problems.- 2.1 The motion processes.- 2.2 Problems of imaging methods.- 2.3 Problems in modelling.- 3. Processing methods for image sequences.- 3.1 Image sequence restoration and enhancement.- 3.2 Quantification of blood dynamics.- 3.3 Quantification of heart dynamics.- 4. Implementation aspects.- 4.1 Hardware 3.- 4.2 Software.- 5. Conclusion.- CT techniques in medical imaging.- 1. Introduction.- 2. X-ray computerized tomography - about the principle and the state-of-the-art.- 3. CT procedures with different information carriers.- 3.1 Emission CT (ECT).- 3.2 Proton CT.- 3.3 Nuclear magnetic resonance imaging.- 3.4 Ultrasonic CT.- 4. Conclusion.- 5. Summary.- Three-dimensional imaging from tomograms.- 1. Introduction.- 2. Discrete 3D scenes.- 3. Objects and their surfaces.- 4. Surface detection of 1-objects in binary scenes.- 5. Display of organ surfaces.- 6. Recent advances in the cuberille approach.- 7. Clinical examples.- 8. Discussion.- High speed acquisition, recognition and retrieval of cells and cell-like objects.- 1. Introduction.- 2. Data acquisition.- 3. Data compression.- 4. Data recall.- 5. Data processing.- 6. Conclusion.- Medical picture base systems.- Abstract.- 1. User's situation.- 2. Technological situation.- 2.1 Mass storage system.- 2.2 Picture input devices.- 2.3 Picture processors.- 2.4 Picture coding.- 3. System aspects.- Planar imaging and picture analysis in nuclear medicine.- 1. Introduction.- 2. Radionuclide image formation.- 2.1 Imaging devices.- 2.2 Imaging agents.- 2.3 Planar imaging.- 2.3.1 Efficiency, resolution, system transfer function.- 2.3.2 Noise, contrast.- 2.3.3 Performance characteristics.- 3. Image analysis.- 3.1 Hardware aspects.- 3.2 Software aspects.- 3.2.1 High level languages.- 3.3 Image processing.- 3.3.1 Curve processing.- 4. Selected applications.- 4.1 Static scintigraphy.- 4.2 Dynamic scintigraphy.- 4.2.1 Functional imaging.- 4.2.2 ECG gated blood pool imaging.- 5. Evaluation (Decision making).- 6. Conclusion.