last modified: 31/10/2002
This concerns a
course |
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ECTS credit points: 3 |
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Faculty of Mechanical Engineering and Marine
Technology |
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Lecturer(s):
Linden, mw.
J. van
der, Valstar, dr.ir. E.R. |
Tel.: 010-4087384
(Van der Linden) |
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Catalog data: |
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(see academic calendar) |
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Detailed description
of topics: Although everybody knows that bone can heal
after it has been fractured, not many people realize that bone is actually
living tissue. This living tissue is able to adapt its architecture to
changes in external loads and to repair damage. Astronauts lose bone mass
during spaceflight, as their skeleton adapts to the low gravity environment.
Tennis players have stronger bones in their dominant arm and high resistance
training, like weight-lifting, increases bone mass. During this lecture series, a number of topics
related to the skeleton, locomotion, bone biology and prostheses will be
discussed. We will also look into the evolution of the skeleton, starting
with the first occurrence of bone tissue in prehistoric fish. Although the
sizes of bones differ between humans and other mammals, the global shape of
the different bones is surprisingly similar. We will give an introduction to
bone biology, examine the bone remodeling process and possible treatments of
degenerative bone diseases. The changes in bone architecture and density
resulting from changes in external loads and implantation of prostheses can
be predicted using finite element modelling. We will show how computer models of the biological system can be
used to e.g. test new prostheses. Fractures in elderly people, especially hip
fractures, have a large effect on their quality of life. Therefore, it is
important to try to prevent these fractures and to keep improving the
treatment of fractures. Implantation of joint prostheses, which partially or completely replace a
diseased joint drastically reduces pain and restores the mobility of the
joint. Although joint prostheses have been used since the 1960's, they are in
no way perfect yet. However, yearly about 1 million total hip prostheses and
750.000 total knee prostheses are implanted worldwide. We will discuss the
development of prostheses and the current state of the art in hip-, knee-,
shoulder-, and elbow prostheses. Furthermore, several biomaterials will be
examined, with their advantages and disadvantages. Taken together, this lecture series will give an
overview of the functioning of the human skeleton, its evolution, growth and
degeneration and artificial prostheses which are frequently used when parts
of the skeleton fail. |
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Learning goals: Knowledge about biology and biomechanics of
bone, design criteria for bone implants, application of tissue mechanics and
Finite Element methods |
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Computer use: |
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