Polymer synthesis and scaffold fabrication
This report is to document the Final Year Project (MSE08-092): Polymer synthesis and scaffold fabrication. Biodegradable elastomeric scaffolds are prepared using molar ratio 1:1 of Malic Acid and 1-12, decandiol. The polymer is synthesized by condensation polymerisation and processed with superc...
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sg-ntu-dr.10356-153702023-03-04T15:38:57Z Polymer synthesis and scaffold fabrication Zeng, Shiyan Tan Lay Poh School of Materials Science and Engineering DRNTU::Engineering::Materials::Biomaterials This report is to document the Final Year Project (MSE08-092): Polymer synthesis and scaffold fabrication. Biodegradable elastomeric scaffolds are prepared using molar ratio 1:1 of Malic Acid and 1-12, decandiol. The polymer is synthesized by condensation polymerisation and processed with supercritical carbon dioxide to produce scaffolds with high porosity and interconnectivity. Thereafter, the fabricated scaffold’s mechanical integrity is then characterized in terms of using mechanical compression testing and the average pore size and porosity is characterized using SEM and Mercury Intrusion Porosimetry respectively. Numerous processing parameters such as double depressurizing methods, polymerization time, post-depressurizing holding pressure, saturation time were being investigated. The most ideal parameters used to fabricate the scaffold are: Polymerization time of 56 hours, using double depressurizing methods which saturates the polymer with the supercritical carbon dioxide for 2 times with a saturation pressure of 3500 psi for 60 minutes each time. Post-depressurizing holding pressure of 100 psi is then applied at the end of the double pressurization process to uphold the scaffold structure for 12 hours. The scaffold is then post cured for 2 weeks before characterization. The completed scaffold is highly interconnected with pore sizes averaging of about 102.646μm with a standard deviation of 20.617μm, and with an average porosity of 65.5186%, it has an elastic modulus of 0.32027 ± 0.04080MPa at body temperature. The scaffold fabricated is also suited for cell culture from cytoxicity tests. Biodegradable elastomeric scaffolds are prepared using molar ratio 1:1 of Malic Acid and 1-12,decandiol. The polymer is synthesized by condensation polymerisation and processed with supercritical carbon dioxide to produce scaffolds with high porosity and interconnectivity. Thereafter, the fabricated scaffold’s mechanical integrity is then characterized in terms of using mechanical compression testing and the average pore size and porosity is characterized using SEM and Mercury Intrusion Porosimetry respectively. Numerous processing parameters such as double depressurizing methods, polymerization time, post-depressurizing holding pressure, saturation time were being investigated. The most ideal parameters used to fabricate the scaffold are: Polymerization time of 56 hours, using double depressurizing methods which saturates the polymer with the supercritical carbon dioxide for 2 times with a saturation pressure of 3500 psi for 60 minutes each time. Post-depressurizing holding pressure of 100 psi is then applied at the end of the double pressurization process to uphold the scaffold structure for 12 hours. The scaffold is then post cured for 2 weeks before characterization. The completed scaffold is highly interconnected with pore sizes averaging of about 102.646μm with a standard deviation of 20.617μm, and with an average porosity of 65.5186%, it has an elastic modulus of 0.32027 ± 0.04080MPa at body temperature. The scaffold fabricated is also suited for cell culture from cytoxicity tests. Bachelor of Engineering (Materials Engineering) 2009-04-28T02:05:14Z 2009-04-28T02:05:14Z 2009 2009 Final Year Project (FYP) http://hdl.handle.net/10356/15370 en 44 p. application/pdf |
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DRNTU::Engineering::Materials::Biomaterials Zeng, Shiyan Polymer synthesis and scaffold fabrication |
| description |
This report is to document the Final Year Project (MSE08-092): Polymer synthesis and scaffold
fabrication.
Biodegradable elastomeric scaffolds are prepared using molar ratio 1:1 of Malic Acid and 1-12,
decandiol. The polymer is synthesized by condensation polymerisation and processed with
supercritical carbon dioxide to produce scaffolds with high porosity and interconnectivity.
Thereafter, the fabricated scaffold’s mechanical integrity is then characterized in terms of using
mechanical compression testing and the average pore size and porosity is characterized using
SEM and Mercury Intrusion Porosimetry respectively.
Numerous processing parameters such as double depressurizing methods, polymerization time,
post-depressurizing holding pressure, saturation time were being investigated. The most ideal
parameters used to fabricate the scaffold are: Polymerization time of 56 hours, using double
depressurizing methods which saturates the polymer with the supercritical carbon dioxide for 2
times with a saturation pressure of 3500 psi for 60 minutes each time. Post-depressurizing
holding pressure of 100 psi is then applied at the end of the double pressurization process to
uphold the scaffold structure for 12 hours. The scaffold is then post cured for 2 weeks before
characterization.
The completed scaffold is highly interconnected with pore sizes averaging of about 102.646μm
with a standard deviation of 20.617μm, and with an average porosity of 65.5186%, it has an
elastic modulus of 0.32027 ± 0.04080MPa at body temperature. The scaffold fabricated is also suited
for cell culture from cytoxicity tests.
Biodegradable elastomeric scaffolds are prepared using molar ratio 1:1 of Malic Acid and 1-12,decandiol. The polymer is synthesized by condensation polymerisation and processed with supercritical carbon dioxide to produce scaffolds with high porosity and interconnectivity.
Thereafter, the fabricated scaffold’s mechanical integrity is then characterized in terms of using mechanical compression testing and the average pore size and porosity is characterized using
SEM and Mercury Intrusion Porosimetry respectively.
Numerous processing parameters such as double depressurizing methods, polymerization time,
post-depressurizing holding pressure, saturation time were being investigated. The most ideal
parameters used to fabricate the scaffold are: Polymerization time of 56 hours, using double depressurizing methods which saturates the polymer with the supercritical carbon dioxide for 2 times with a saturation pressure of 3500 psi for 60 minutes each time. Post-depressurizing holding pressure of 100 psi is then applied at the end of the double pressurization process to uphold the scaffold structure for 12 hours. The scaffold is then post cured for 2 weeks before characterization.
The completed scaffold is highly interconnected with pore sizes averaging of about 102.646μm with a standard deviation of 20.617μm, and with an average porosity of 65.5186%, it has an elastic modulus of 0.32027 ± 0.04080MPa at body temperature. The scaffold fabricated is also suited
for cell culture from cytoxicity tests. |
| author2 |
Tan Lay Poh |
| author_facet |
Tan Lay Poh Zeng, Shiyan |
| format |
Final Year Project |
| author |
Zeng, Shiyan |
| author_sort |
Zeng, Shiyan |
| title |
Polymer synthesis and scaffold fabrication |
| title_short |
Polymer synthesis and scaffold fabrication |
| title_full |
Polymer synthesis and scaffold fabrication |
| title_fullStr |
Polymer synthesis and scaffold fabrication |
| title_full_unstemmed |
Polymer synthesis and scaffold fabrication |
| title_sort |
polymer synthesis and scaffold fabrication |
| publishDate |
2009 |
| url |
http://hdl.handle.net/10356/15370 |
| _version_ |
1759853119007621120 |