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Abstract

Background

Tissue engineering of nasal septal cartilage has been the focus of research owing to its superior structural rigidity and ease of harvest. In vitro constructs formed from septal chondrocytes using fibrin glue within a polyglycolic acid (PGA) scaffold have been shown to be viable, but their cellular growth and expression of differentiated features still have not been quantified. In this study, we evaluated cellular proliferation and production of cartilaginous extracellular matrix (ECM) components in fibrin glue preparations within a PGA scaffold.

Methods

Human chondrocytes were expanded for one passage in monolayer in culture medium. The cells were then grown in (1) fibrinogen, 1/2×–thrombin, 1/2× (F/2:T/2); (2) fibrinogen, 1/10×–thrombin, 1/10× (F/10:T/10); (3) fibrinogen, 1×–thrombin, 1/100× (F/1:T/100).

Results

Cellular proliferation and glycosaminoglycan (GAG) production per cell were highest in the F/2:T/2 preparations. Greater proliferation was seen in chondrocyte–fibrin composites seeded onto the PGA scaffold when compared with chondrocytes seeded onto the PGA scaffold alone. No significant difference in GAG production was seen.

Conclusions

The addition of fibrin glue to chondrocytes seeded onto a PGA scaffold results in increased cellular proliferation while maintaining production of ECM components. Long-term stable fibrin gels in combination with PGA scaffolds may facilitate generation of cartilaginous tissue for use in reconstructive surgery.

Keywords

Cellular proliferation fibrin glue glycosaminoglycan human chondrocytes polyglycolic acid scaffold septal cartilage tissue engineering

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Growth of Human Septal Chondrocytes in Fibrin Scaffolds

Abstract

Background

Methods

Results

Conclusions

Keywords

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References