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3D printed mesh reinforcements enhance the mechanical properties of electrospun scaffolds.
Pensa, Nicholas W; Curry, Andrew S; Bonvallet, Paul P; Bellis, Nathan F; Rettig, Kayla M; Reddy, Michael S; Eberhardt, Alan W; Bellis, Susan L.
Afiliação
  • Pensa NW; 1Department of Biomedical Engineering, University of Alabama at Birmingham, Birmingham, USA.
  • Curry AS; 1Department of Biomedical Engineering, University of Alabama at Birmingham, Birmingham, USA.
  • Bonvallet PP; 2Department of Cell, Developmental and Integrative Biology, University of Alabama at Birmingham, Birmingham, USA.
  • Bellis NF; 2Department of Cell, Developmental and Integrative Biology, University of Alabama at Birmingham, Birmingham, USA.
  • Rettig KM; 1Department of Biomedical Engineering, University of Alabama at Birmingham, Birmingham, USA.
  • Reddy MS; 3School of Dentistry, University of California at San Francisco, San Francisco, USA.
  • Eberhardt AW; 1Department of Biomedical Engineering, University of Alabama at Birmingham, Birmingham, USA.
  • Bellis SL; 2Department of Cell, Developmental and Integrative Biology, University of Alabama at Birmingham, Birmingham, USA.
Biomater Res ; 23: 22, 2019.
Article em En | MEDLINE | ID: mdl-31798944
BACKGROUND: There is substantial interest in electrospun scaffolds as substrates for tissue regeneration and repair due to their fibrous, extracellular matrix-like composition with interconnected porosity, cost-effective production, and scalability. However, a common limitation of these scaffolds is their inherently low mechanical strength and stiffness, restricting their use in some clinical applications. In this study we developed a novel technique for 3D printing a mesh reinforcement on electrospun scaffolds to improve their mechanical properties. METHODS: A poly (lactic acid) (PLA) mesh was 3D-printed directly onto electrospun scaffolds composed of a 40:60 ratio of poly(ε-caprolactone) (PCL) to gelatin, respectively. PLA grids were printed onto the electrospun scaffolds with either a 6 mm or 8 mm distance between the struts. Scanning electron microscopy was utilized to determine if the 3D printing process affected the archtitecture of the electrospun scaffold. Tensile testing was used to ascertain mechanical properties (strength, modulus, failure stress, ductility) of both unmodified and reinforced electrospun scaffolds. An in vivo bone graft model was used to assess biocompatibility. Specifically, reinforced scaffolds were used as a membrane cover for bone graft particles implanted into rat calvarial defects, and implant sites were examined histologically. RESULTS: We determined that the tensile strength and elastic modulus were markedly increased, and ductility reduced, by the addition of the PLA meshes to the electrospun scaffolds. Furthermore, the scaffolds maintained their matrix-like structure after being reinforced with the 3D printed PLA. There was no indication at the graft/tissue interface that the reinforced electrospun scaffolds elicited an immune or foreign body response upon implantation into rat cranial defects. CONCLUSION: 3D-printed mesh reinforcements offer a new tool for enhancing the mechanical strength of electrospun scaffolds while preserving the advantageous extracellular matrix-like architecture. The modification of electrospun scaffolds with 3D-printed reinforcements is expected to expand the range of clinical applications for which electrospun materials may be suitable.
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Texto completo: 1 Coleções: 01-internacional Base de dados: MEDLINE Idioma: En Revista: Biomater Res Ano de publicação: 2019 Tipo de documento: Article

Texto completo: 1 Coleções: 01-internacional Base de dados: MEDLINE Idioma: En Revista: Biomater Res Ano de publicação: 2019 Tipo de documento: Article