Medical physics  

Interaction of non-ionizing electromagnetic waves with matter and tissues • physical models • relaxation processes • effects of low-frequent ( 100 kHz) and high-frequent (>100 kHz) radiowaves. • interactions with ultraviolet radiation. Interaction of ionizing electromagnetic waves with matter and tissues • fundamental interactions at the atomic level: photoelectric effect, compton scattering, • pair formation • attenuation and absorption of X-rays • effects at cellular level • dosimetry of ionizing radiation: exposure, kerma, absorbed dose, equivalent dose, • effective dose Conventional imaging in radiology • screen-film technology for conventional radiography and mammography • digital radiology: computed radiography and direct read-out radiography • analysis of image quality, CAD • patient dosimetry Computed Tomography • CT-technology: spiral CT, multi-slice CT • 3D-applications, CAD • image quality analysis • patient dosimetry Interventional radiology and cardiology • physical principles of fluoroscopy and cinegraphy with image intensifiers • flat-panel systems in interventional radiology/cardiology • cone-beam CT • CT-angiography . • patient dosimetry Ultrasound • physical models of interaction of sound waves with matter and tissues • acoustic impedance • ultrasound: principles and image formation chain Magnetic resonance imaging • MR models • MR relaxation in tissues • MR signals and diffusion • field gradients for location in space Nuclear medicine • overview of radioactive decay modes • production of radionuclides for medical purposes: cyclotron, reactor • nuclear medical imaging: gammacamera, SPECT, PET • therapeutis applications of radionuclides • patient dosimetry in nuclear medicine Radiotherapy • Medical linear accelerator • Absolute dose determination • Patient dosimetry: treatment planning. Final competences: 1 Understand the physical concepts used in medicine. 2 Describe the physical operation of medical imaging instruments. 3 Evaluate the advantages and disadvantages of medical imaging techniques. 4 Apply the principles of radiation dosimetry in different clinical disciplines. 5 Be aware of the need of a medical physicist in a hospital environment.
Presential
English
Medical physics
English

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