Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications
Porous scaffolds manufactured via powder metallurgy and sintering were designed for their structure (i.e. pore size and porosity) and mechanical properties (stiffness, strength) to be controlled and tailored to mimic those of human bone. The scaffolds were realised to fulfil three main objectives: (...
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rr-article-95606662018-01-01T00:00:00Z Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications Carmen Torres (1259328) John McLaughlin (227368) Andrea Fotticchia (7204088) Mechanical engineering not elsewhere classified Condensed matter physics not elsewhere classified TiNbSn Elastic modulus Compressive strength Spaceholder Relative density Trabecular bone Mechanical Engineering not elsewhere classified Condensed Matter Physics Porous scaffolds manufactured via powder metallurgy and sintering were designed for their structure (i.e. pore size and porosity) and mechanical properties (stiffness, strength) to be controlled and tailored to mimic those of human bone. The scaffolds were realised to fulfil three main objectives: (i) to obtain values of stiffness and strength similar to those of trabecular (or spongy) bone, with a view of exploiting these as bone grafts that permit cell regeneration, (ii) to establish a relationship between stiffness, strength and density that allows tailoring for mass customisation to suit patient's needs; and (iii) to assess alloy cytotoxicity and biocompatibility via in vitro studies. The results obtained using a very low stiffness alloy (Ti35Nb4Sn) further lowered with the introduction of nominal porosity (30–70%) with pores in the ranges 180–300 μm and 300–500 μm showed compatibility for anatomical locations typically subjected to implantation and bone grafting (femoral head and proximal tibia). The regression fitting parameters for the linear and power law regressions were similar to those found for bone specimens, confirming a structure favourable to capillary network formation. Biological tests confirmed non-cytotoxicity of the alloy. Scaffolds of porosity nominal 50%vol and pore range 300–500 μm performed best in the adhesion and propagation assays due to a good balance between surface area and pore cavity volume. 2018-01-01T00:00:00Z Text Journal contribution 2134/26913 https://figshare.com/articles/journal_contribution/Porosity_and_pore_size_effect_on_the_properties_of_sintered_Ti35Nb4Sn_alloy_scaffolds_and_their_suitability_for_tissue_engineering_applications/9560666 CC BY-NC-ND 4.0 |
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Mechanical engineering not elsewhere classified Condensed matter physics not elsewhere classified TiNbSn Elastic modulus Compressive strength Spaceholder Relative density Trabecular bone Mechanical Engineering not elsewhere classified Condensed Matter Physics |
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Mechanical engineering not elsewhere classified Condensed matter physics not elsewhere classified TiNbSn Elastic modulus Compressive strength Spaceholder Relative density Trabecular bone Mechanical Engineering not elsewhere classified Condensed Matter Physics Carmen Torres John McLaughlin Andrea Fotticchia Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications |
| description |
Porous scaffolds manufactured via powder metallurgy and sintering were designed for their structure (i.e. pore size and porosity) and mechanical properties (stiffness, strength) to be controlled and tailored to mimic those of human bone. The scaffolds were realised to fulfil three main objectives: (i) to obtain values of stiffness and strength similar to those of trabecular (or spongy) bone, with a view of exploiting these as bone grafts that permit cell regeneration, (ii) to establish a relationship between stiffness, strength and density that allows tailoring for mass customisation to suit patient's needs; and (iii) to assess alloy cytotoxicity and biocompatibility via in vitro studies. The results obtained using a very low stiffness alloy (Ti35Nb4Sn) further lowered with the introduction of nominal porosity (30–70%) with pores in the ranges 180–300 μm and 300–500 μm showed compatibility for anatomical locations typically subjected to implantation and bone grafting (femoral head and proximal tibia). The regression fitting parameters for the linear and power law regressions were similar to those found for bone specimens, confirming a structure favourable to capillary network formation. Biological tests confirmed non-cytotoxicity of the alloy. Scaffolds of porosity nominal 50%vol and pore range 300–500 μm performed best in the adhesion and propagation assays due to a good balance between surface area and pore cavity volume. |
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Default Article |
| author |
Carmen Torres John McLaughlin Andrea Fotticchia |
| author_facet |
Carmen Torres John McLaughlin Andrea Fotticchia |
| author_sort |
Carmen Torres (1259328) |
| title |
Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications |
| title_short |
Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications |
| title_full |
Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications |
| title_fullStr |
Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications |
| title_full_unstemmed |
Porosity and pore size effect on the properties of sintered Ti35Nb4Sn alloy scaffolds and their suitability for tissue engineering applications |
| title_sort |
porosity and pore size effect on the properties of sintered ti35nb4sn alloy scaffolds and their suitability for tissue engineering applications |
| publishDate |
2018 |
| url |
https://hdl.handle.net/2134/26913 |
| _version_ |
1797282344624717824 |