Towards the delivery of nano devices for functioning inside a living cell
Shape Memory Materials (SMMs) are novel materials that have the ability to recover their original shape even after severe deformations. There has been much interest surrounding this type of materials, due to this Shape Memory Effect property. Moreover, a wide variety of different breeds of...
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Format: | Final Year Project |
Language: | English |
Published: |
2011
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Online Access: | http://hdl.handle.net/10356/46065 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | Shape Memory Materials (SMMs) are novel materials that have the ability to
recover their original shape even after severe deformations. There has been much
interest surrounding this type of materials, due to this Shape Memory Effect property.
Moreover, a wide variety of different breeds of SMM can be produced to suit
different applications.
In this report, the focus will be on Shape Memory Polymers (SMPs), a class of
SMM, to assess its viability to be applied to Biomedical technology. SMPs are a
cheaper alternative to its SMM counterparts, lightweight, and most importantly
biocompatible. Some are even biodegradable.
SMP wires are fabricated to obtain a coiled permanent shape, after which they
are straightened to a temporary shape by heating it to above its glass transition
temperature, Tg.
Two separate tests were carried out to test the recovery of the wires in toad
embryo. In the first test, the SMP wire was injected into the eggs immediately after
fabrication. Observations were then made at room temperature (25°C), and when the
egg sample was heated to different temperatures. Significant recovery was observed
at a temperature of 45°C
In the second test, the initial condition of the SMP wire was altered. It was
immersed in water for a day before insertion, and left in the eggs for a week before
the heating process. Slight recovery was found even before the heating process.
Furthermore, signs of significant recovery in this second test was evident at 37.5°C,
similar to the human body temperature.
This result is parallel to evidence of decreased Tg of SMPs when exposed to
moisture. This means that the SMP absorbed moisture, which changed its structure,
and lower energy is now required for the SMP to return to its original shape. |
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