Search result: Catalogue data in Spring Semester 2018
MAS in Medical Physics | ||||||
Specialization: General Medical Physics and Biomedical Engineering | ||||||
Major in Bioengineering | ||||||
Core Courses | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
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376-1392-00L | Mechanobiology: Implications for Development, Regeneration and Tissue Engineering | W | 3 credits | 2G | A. Ferrari, K. Würtz-Kozak, M. Zenobi-Wong | |
Abstract | This course will emphasize the importance of mechanobiology to cell determination and behavior. Its importance to regenerative medicine and tissue engineering will also be addressed. Finally, this course will discuss how age and disease adversely alter major mechanosensitive developmental programs. | |||||
Learning objective | This course is designed to illuminate the importance of mechanobiological processes to life as well as to teach good experimental strategies to investigate mechanobiological phenomena. | |||||
Content | Typically, cell differentiation is studied under static conditions (cells grown on rigid plastic tissue culture dishes in two-dimensions), an experimental approach that, while simplifying the requirements considerably, is short-sighted in scope. It is becoming increasingly apparent that many tissues modulate their developmental programs to specifically match the mechanical stresses that they will encounter in later life. Examples of known mechanosensitive developmental programs include all forms of myogenesis (cardiac, skeletal and smooth muscles), osteogenesis (bones), chondrogenesis (cartilage), tendogenesis (tendons) and angiogenesis (blood vessels). Furthermore, general forms of cell behavior such as migration, extracellular matrix deposition, and complex tissue differentiation are also regulated by mechanical stimuli. Mechanically-regulated cellular processes are thus ubiquitous, ongoing and of great clinical importance. The overall importance of mechanobiology to humankind is illustrated by the fact that nearly 80% of our entire body mass arises from tissues originating from mechanosensitive developmental programs, principally bones and muscles. Unfortunately, our ability to regenerate mechanosensitive tissue diminishes in later life. As it is estimated that the fraction of the western world population over 65 years of age will double in the next 25 years, an urgency in the global biomedical arena exists to better understand how to optimize complex tissue development under physiologically-relevant mechanical environments for purposes of regenerative medicine and tissue engineering. | |||||
Lecture notes | n/a | |||||
Literature | Topical Scientific Manuscripts | |||||
376-1614-00L | Principles in Tissue Engineering | W | 3 credits | 2V | K. Maniura, J. Möller, M. Zenobi-Wong | |
Abstract | Fundamentals in blood coagulation; thrombosis, blood rheology, immune system, inflammation, foreign body reaction on the molecular level and the entire body are discussed. Applications of biomaterials for tissue engineering in different tissues are introduced. Fundamentals in medical implantology, in situ drug release, cell transplantation and stem cell biology are discussed. | |||||
Learning objective | Understanding of molecular aspects for the application of biodegradable and biocompatible Materials. Fundamentals of tissue reactions (eg. immune responses) against implants and possible clinical consequences will be discussed. | |||||
Content | This class continues with applications of biomaterials and devices introduced in Biocompatible Materials I. Fundamentals in blood coagulation; thrombosis, blood rheology; immune system, inflammation, foreign body reaction on the level of the entire body and on the molecular level are introduced. Applications of biomaterials for tissue engineering in the vascular system, skeletal muscle, heart muscle, tendons and ligaments, bone, teeth, nerve and brain, and drug delivery systems are introduced. Fundamentals in medical implantology, in situ drug release, cell transplantation and stem cell biology are discussed. | |||||
Lecture notes | Handouts provided during the classes and references therin. | |||||
Literature | The molecular Biology of the Cell, Alberts et al., 5th Edition, 2009. Principles in Tissue Engineering, Langer et al., 2nd Edition, 2002 |
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