Laboratory exercises:
The field of Radiodiagnostics:
1) History of the discovery of X-rays, history and development of radiological instruments. X-ray tube, design, principle of operation. Generation of X-rays. Instrumentation for scanning, technical design, principle, clinical application. Instrumentation for skiascopy, technical design, principle, clinical use. Primary aperture, technical design, use. Secondary aperture, technical solution, application. Exposure automation, principle of operation, clinical use.
2) Computed tomography (CT) - computed tomography, generation of CT scanners, technical design, working principle and clinical use of CT. Post-processing methods of CT. Possibilities of using 3D data, 3D printing in radiology.
3) Digital subtraction angiography, principle of operation, clinical use, possibilities of interventional radiology.3D angiography, postprocessing methods in 3D angiography.
4) Ultrasonography, basic technical principle, clinical applications. Ultravascular ultrasound (IVUS) - technical principle, clinical use. Endoscopic ultrasound (EUS) - technical principle, clinical application.
5) Magnetic resonance imaging (MRI), basic technical principle, technical design and clinical use of MRI. DICOM standard. Data archiving in radiology. PACS systems.
Area of Radiotherapy:
1) History and development of radiotherapy. 1. Radiation protection. Physical basis for radiotherapy. Audits in RT.
2) Basic types of instrumentation in radiotherapy. Irradiators for RT - radionuclide, therapeutic RT, linear accelerators - construction, characteristics. Image guided radiotherapy.
3) Radiosurgery, instrumentation for radiosurgery and stereotactic RT.
4) Brachytherapy - design of devices for AFL. Safety features in RT. QA - operational stability and long-term stability testing.
5) Radiotherapy planning. Fundamentals of metrological procedures applied in radiotherapy. Current legislation relating to radiotherapy.
Translated with www.DeepL.com/Translator (free version)
The field of Radiodiagnostics:
1) History of the discovery of X-rays, history and development of radiological instruments. X-ray tube, design, principle of operation. Generation of X-rays. Instrumentation for scanning, technical design, principle, clinical application. Instrumentation for skiascopy, technical design, principle, clinical use. Primary aperture, technical design, use. Secondary aperture, technical solution, application. Exposure automation, principle of operation, clinical use.
2) Computed tomography (CT) - computed tomography, generation of CT scanners, technical design, working principle and clinical use of CT. Post-processing methods of CT. Possibilities of using 3D data, 3D printing in radiology.
3) Digital subtraction angiography, principle of operation, clinical use, possibilities of interventional radiology.3D angiography, postprocessing methods in 3D angiography.
4) Ultrasonography, basic technical principle, clinical applications. Ultravascular ultrasound (IVUS) - technical principle, clinical use. Endoscopic ultrasound (EUS) - technical principle, clinical application.
5) Magnetic resonance imaging (MRI), basic technical principle, technical design and clinical use of MRI. DICOM standard. Data archiving in radiology. PACS systems.
Area of Radiotherapy:
1) History and development of radiotherapy. 1. Radiation protection. Physical basis for radiotherapy. Audits in RT.
2) Basic types of instrumentation in radiotherapy. Irradiators for RT - radionuclide, therapeutic RT, linear accelerators - construction, characteristics. Image guided radiotherapy.
3) Radiosurgery, instrumentation for radiosurgery and stereotactic RT.
4) Brachytherapy - design of devices for AFL. Safety features in RT. QA - operational stability and long-term stability testing.
5) Radiotherapy planning. Fundamentals of metrological procedures applied in radiotherapy. Current legislation relating to radiotherapy.
Translated with www.DeepL.com/Translator (free version)