Sebastian Kozerke: Catalogue data in Spring Semester 2019

Name Prof. Dr. Sebastian Kozerke
FieldBiomedical Imaging
Address
Professur für Biomed. Bildgebung
ETH Zürich, ETZ F 94
Gloriastrasse 35
8092 Zürich
SWITZERLAND
Telephone+41 44 632 35 49
E-mailkozerke@biomed.ee.ethz.ch
DepartmentInformation Technology and Electrical Engineering
RelationshipFull Professor

NumberTitleECTSHoursLecturers
227-0383-00LMedical Imaging I Restricted registration - show details
Only for Human Medicine BSc
3 credits3GS. Kozerke, O. Göksel, R. Schibli, M. P. Wolf
AbstractThe course introduces the foundations of noninvasive imaging including X-ray imaging, Computed Tomography, Magnetic Resonance Imaging, Single Photon and Positron Emission Tomography, Ultrasound and Optical Imaging. Besides the physical and technical methodology, the assessment of imaging performance is covered to enable students to identify relative advantages and limitations.
Learning objectiveThe course enables students to
1) explain the physical and technical foundations of medical imaging,
2) characterise imaging performance,
3) interpret and analyse image content and
4) make an informed choice of modalities for a given clinical question.
ContentIntroduction + Example case
X-ray and Computed Tomography
Magnetic Resonance Imaging
Nuclear Imaging
Ultrasound Imaging
Optical Imaging
Hybrid Imaging
Clinical imaging case pitches
Summary
227-0396-00LEXCITE Interdisciplinary Summer School on Bio-Medical Imaging Information Restricted registration - show details
The school admits 60 MSc or PhD students with backgrounds in biology, chemistry, mathematics, physics, computer science or engineering based on a selection process.

Students have to apply for acceptance by April 22, 2019. To apply a curriculum vitae and an application letter need to be submitted. The notification of acceptance will be given by May 24, 2019. Further information can be found at: www.excite.ethz.ch.
4 credits6GS. Kozerke, G. Csúcs, J. Klohs-Füchtemeier, S. F. Noerrelykke, M. P. Wolf
AbstractTwo-week summer school organized by EXCITE (Center for EXperimental & Clinical Imaging TEchnologies Zurich) on biological and medical imaging. The course covers X-ray imaging, magnetic resonance imaging, nuclear imaging, ultrasound imaging, infrared and optical microscopy, electron microscopy, image processing and analysis.
Learning objectiveStudents understand basic concepts and implementations of biological and medical imaging. Based on relative advantages and limitations of each method they can identify preferred procedures and applications. Common foundations and conceptual differences of the methods can be explained.
ContentTwo-week summer school on biological and medical imaging. The course covers concepts and implementations of X-ray imaging, magnetic resonance imaging, nuclear imaging, ultrasound imaging, infrared and optical microscopy and electron microscopy. Multi-modal and multi-scale imaging and supporting technologies such as image analysis and modeling are discussed. Dedicated modules for physical and life scientists taking into account the various backgrounds are offered.
Lecture notesHand-outs, Web links
Prerequisites / NoticeThe school admits 60 MSc or PhD students with backgrounds in biology, chemistry, mathematics, physics, computer science or engineering based on a selection process. To apply a curriculum vitae, a statement of purpose and applicants references need to be submitted. Further information can be found at: http://www.excite.ethz.ch/education/summer-school.html
227-0948-00LMagnetic Resonance Imaging in Medicine4 credits3GS. Kozerke, M. Weiger Senften
AbstractIntroduction to magnetic resonance imaging and spectroscopy, encoding and contrast mechanisms and their application in medicine.
Learning objectiveUnderstand the basic principles of signal generation, image encoding and decoding, contrast manipulation and the application thereof to assess anatomical and functional information in-vivo.
ContentIntroduction to magnetic resonance imaging including basic phenomena of nuclear magnetic resonance; 2- and 3-dimensional imaging procedures; fast and parallel imaging techniques; image reconstruction; pulse sequences and image contrast manipulation; equipment; advanced techniques for identifying activated brain areas; perfusion and flow; diffusion tensor imaging and fiber tracking; contrast agents; localized magnetic resonance spectroscopy and spectroscopic imaging; diagnostic applications and applications in research.
Lecture notesD. Meier, P. Boesiger, S. Kozerke
Magnetic Resonance Imaging and Spectroscopy
227-0980-00LSeminar on Biomedical Magnetic Resonance Information 0 credits1SK. P. Prüssmann, S. Kozerke
AbstractActuel developments and problems of magnetic resonance imaging (MRI)
Learning objectiveGetting insight to advanced topics in Magnetic Resonance Imaging