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TitleIndirect printing of hierarchical patient‑specifc scafolds for meniscus tissue engineering
Author(s)Costa, João B.
Silva-Correia, Joana
Pina, Sandra Cristina Almeida
da Silva Morais, Alain
Vieira, Sílvia Cristina Araújo
Pereira, H.
Espregueira-Mendes, João
Reis, R. L.
Oliveira, J. M.
Indirect printing
Silk fbroin
Silk fibroin
Issue dateAug-2019
JournalBio-Design and Manufacturing
CitationCosta J. B., Silva-Correia J., Pina S., da Silva Morais A., Vieira S., Pereira H., Espregueira-Mendes J., Reis R. L., Oliveira J. M. Indirect printing of hierarchical patient‑specifc scafolds for meniscus tissue engineering, Bio-Design and Manufacturing, pp. 1-17, doi:10.1007/s42242-019-00050-x, 2019
Abstract(s)The complex meniscus tissue plays a critical role in the knee. The high susceptibility to injury has led to an intense pursuit for better tissue engineering regenerative strategies, where scafolds play a major role. In this study, indirect printed hierarchical multilayered scafolds composed by a silk fbroin (SF) upper layer and an 80/20 (w/w) ratio of SF/ionic-doped β-tricalcium phosphate (TCP) bottom layer were developed. Furthermore, a comparative analysis between two types of scafolds produced using diferent SF concentrations, i.e., 8% (w/v) (Hi8) and 16% (w/v) (Hi16) was performed. In terms of architecture and morphology, the produced scafolds presented homogeneous porosity in both layers and no diferences were observed when comparing both scafolds. A decrease in terms of mechanical performance of the scafolds was observed when SF concentration decreased from 16 to 8% (w/v). Hi16 revealed a static compressive modulus of 0.66±0.05 MPa and dynamical mechanical properties ranging from 2.17±0.25 to 3.19±0.38 MPa. By its turn, Hi8 presented a compressive modulus of 0.27±0.08 MPa and dynamical mechanical properties ranging from 1.03±0.08 MPa to 1.56±0.13 MPa. In vitro bioactivity studies showed formation of apatite crystals onto the surface of Hi8 and Hi16 bottom layers. Human meniscus cells (hMCs) and human primary osteoblasts were cultured separately onto the top layer (SF8 and SF16) and bottom layer (SF8/TCP and SF16/TCP) of the hierarchical scafolds Hi8 and Hi16, respectively. Both cell types showed good adhesion and proliferation as denoted by the live/dead staining, Alamar Blue assay and DNA quantifcation analysis. Subcutaneous implantation in mice revealed weak infammation and scafoldâ s integrity. The hierarchical indirect printed SF scafolds can be promising candidate for meniscus TE scafolding applications due their suitable mechanical properties, good biological performance and possibility of being applied in a patient-specifc approach.
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Appears in Collections:3B’s - Artigos em revistas/Papers in scientific journals

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