The bachelor's thesis is the culmination of the program. The students develop, enhance, and demonstrate their methodological abilities to independently tackle and solve a given research problem. The thesis furnishes the students with their first major research experience, and is a further development of the work done in the basis courses, and usually, the focused study.

In this course, students attend 14 colloquium sessions featuring talks by PhD candidates, postdocs and senior researchers from academia and industry. Students must participate in at least 10 sessions and write abstracts for 10 presentations, broadening their biomechanics knowledge and sharpening scientific communication.

Demonstration verschiedener Einsatzbereiche des Computers in der Erarbeitung eines wissenschaftlichen Projektes der Medizinphysik.

Significance and tasks of Biomedical Engineering in medical research and practice. Overview over the field and major areas of interest, examples.

Independent studies on a defined field in biomedical engineering.

Independent studies on a defined field in biomedical engineering.

Imaging and computing methods are key to advances and innovation in medicine. This course introduces established fundamentals as well as modern techniques and methods of imaging and computing in medicine.

Significance and tasks of Biomedical Engineering in medical research and practice. Overview over the field and major areas of interest, examples.

The thesis is the final work of the Master program. It promotes the students abilities to develop and solve a research problem independently, structured under methodological considerations. The thesis is based on the studies of Bachelor program and the lectures of the Master Program.

In agreement with the lecturers a semester paper in the context of the topics discussed in the lectures can be written.

The lecture introduces the physical and technical know-how of X-ray tomographic microscopy. Several X-ray imaging techniques (absorption-, phase- and darkfield contrast) will be discussed and their use in daily research, in particular biology, is presented. The course discusses the aspects of quantitative evaluation of tomographic data sets like segmentation, morphometry and statistics.

The seminar provides state-of-the-art insight to the biomechanical function of bone from molecules, to cells, tissue and up to the organ. Multiscale imaging and simulation allows linking different levels of hierarchy, where systems biology helps understanding the mechanobiological response of bone to loading and injury in scenarios relevant for personalized health and translational medicine.

This course is aimed at studying the mechanical and structural engineering of the musculoskeletal system alongside the analysis and design of orthopaedic solutions to musculoskeletal failure.

Introduction to the basic concepts of orthopaedic science with special emphasis on bioengineering.

This course is aimed at studying the mechanical and structural engineering of the musculoskeletal system alongside the analysis and design of orthopaedic solutions to musculoskeletal failure.

Current topics in Biomedical Engineering presented by speakers from academia and industry.

Collaboration in a research project. Insight into research methods and laboratory procedures. Collaboration in a project of choice within the groups bioimaging, biomechanics, medical optics or cellular mechanics.