Polyurethane porous scaffolds (PPS) for soft tissue regenerative medicine applications

Tissue engineering requires suitable polymeric scaffolds, which act as a physical support for regenerated tissue. A promising candidate might be polyurethane (PUR) scaffold, due to the ease of the PUR properties design, which can be adjusted directly to the intended purpose. In this study, we report...

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Bibliographic Details
Published in:Polymer bulletin (Berlin, Germany) Germany), 2018-05, Vol.75 (5), p.1957-1979
Main Authors: Kucińska-Lipka, J., Gubanska, I., Pokrywczynska, M., Ciesliński, H., Filipowicz, N., Drewa, T., Janik, H.
Format: Article
Language:English
Subjects:
Aorta
Biocompatibility
Biodegradation
Biomedical materials
Blood vessels
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Complex Fluids and Microfluidics
Contact angle
Design
Distilled water
E coli
Leaching
Mechanical properties
Medical equipment
Morphology
Organic Chemistry
Original Paper
Phase separation
Photomicrographs
Physical Chemistry
Polymer Sciences
Polymers
Polyurethane resins
Pore size
Regenerative medicine
Saline solutions
Scaffolds
Soft and Granular Matter
Soft tissues
Solvents
Tensile strength
Tissue engineering
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Summary:Tissue engineering requires suitable polymeric scaffolds, which act as a physical support for regenerated tissue. A promising candidate might be polyurethane (PUR) scaffold, due to the ease of the PUR properties design, which can be adjusted directly to the intended purpose. In this study, we report a successful fabrication of porous polyurethane scaffolds (PPS) using solvent casting/particulate leaching technique combined with thermally induced phase separation. The obtained PPS had comparable chemical structure to native PUR, which was confirmed by FTIR and HNMR analyses. The performed DSC study determined a similar T g of the obtained PPS to native PUR (−38 °C). The analysis of TEM micrographs revealed that PPS had a homogenous structure. The studied PPS interactions with canola oil, distilled water, saline solution and phosphate-buffered saline after 3 months of incubation revealed that these materials have stable character in these media. The significant decrease of contact angle from 68° for native PUR to 54° for PPS was noted, as well as the decrease of mechanical properties ( T Sb  ~ 1 MPa and ε b  ~ 95% of PPS were comparable to the native aorta tissue of T Sb  ~ 0.3–0.8 MPa and ε b  ~ 50–100%). Through SEM analysis, the morphology of the PPS was determined: the porosity was 87% and the pore sizes in the range of 98–492 µm. The biological studies revealed that the obtained PPS are sensitive to microorganisms such as Staphylococcus aureus , Pseudomonas aeruginosa and Escherichia coli and that they are biocompatible with the 3T3 NIH cell line. In summary, the obtained PPS scaffolds may be a suitable material for soft tissue engineering like blood vessels.
ISSN:0170-0839
1436-2449
DOI:10.1007/s00289-017-2124-x