Cell-based tissue engineering is a promising approach for treating cartilage lesions but the optimal cell-scaffold combination for hyaline cartilage regeneration has yet to be identified. Novel hydrogels allow including tailored tissue type specific modifications with physiologically relevant peptides, by this selectively influencing the cell response. Aim of this study was to modify a poly(ethylene glycol) (PEG)/heparin hydrogel by functionalization with cell instructive peptides introducing matrix-metalloprotease (MMP)-degradability, the cell adhesion motif RGD, or collagen binding motifs (CKLER, CWYRGRL) to improve cartilage matrix deposition in tissue engineering constructs.

The hydrogels were formed by mixing thiol-endfunctionalized (MMP-insensitive) starPEG or starPEG-MMP-conjugates carrying MMP-sensitive peptides at every arm and maleimide-functionalized heparin [1] in the presence or absence of cell instructive peptides. Human mesenchymal stromal cells (MSC) or porcine chondrocytes were grown in the hydrogels for up to 4 weeks in vitro under chondrogenic conditions, and in vivo in subcutaneous pockets of immunodeficient mice.

MMP-sensitive and –insensitive starPEG/heparin hydrogels supported chondrogenic differentiation of MSC according to induction of COL2A1, BGN and ACAN mRNA expression. Enhanced MMP-sensitivity and therefore degradability increased cell viability and proliferation. RGD-modification of the hydrogels induced cell-spreading and an intensively interconnected cell network. Other than hypothesized, CKLER and CWYRGRL were unable to raise collagen deposition in constructs in vitro. Matrix deposition in chondrocyte-containing peptide-functionalized hydrogels was high and the instructive effect of the hydrogels on chondrocytes appeared stronger in vivo where the merely pericellular cartilaginous matrix deposition was overcome in RGD-functionalized starPEG/heparin hydrogels.

Peptide-functionalized starPEG/heparin hydrogel altered cell morphology, proliferation and differentiation with MSC being similar sensitive to cell-matrix interaction peptides like articular chondrocytes. We also demonstrated that in vivoperformance of cell instructive hydrogels can exceed results gained by in vitromodels. Altogether, the manipulation of hydrogel constructs with signaling cues is considered promising for functional cartilage tissue engineering.

Long-term regeneration of cartilage defects treated with tissue engineering constructs often fails because of insufficient integration with the host tissue. We hypothesize that construct integration will be improved when implants actively interact with and integrate into the subchondral bone. Growth and Differentiation Factor 5 (GDF-5) is known to support maturation of chondrocytes and to enhance chondrogenic differentiation and hypertrophy of mesenchymal stromal cells (MSC). Therefore, we investigated whether GDF-5 is capable to stimulate endochondral ossification of MSC in vitro and in vivo and would, thus, be a promising candidate for augmenting fibrin glue in order to support integration of tissue engineering constructs into the subchondral bone plate.

To evaluate the adhesive strength of fibrin glue versus BioGlue^®, a commercially available glue used in vascular surgery, an ex vivo cadaver study was performed and adhesion strength was measured via pull-out testing. MSC were suspended in fibrin glue and cultivated in chondrogenic medium with and without 150 ng/mL GDF-5. After 4 weeks, the formed cartilage was evaluated and half of the constructs were implanted subcutaneously into immunodeficient mice. Endochondral ossification was evaluated after 2 and 4 weeks histologically and by microCT analysis. BioGlue^®and GDF-5-augmented fibrin glue were tested for 4 weeks in a minipig cartilage defect model to assess their orthotopic biocompatibility.

Pull-out testing revealed sufficient adhesive strength of fibrin glue to fix polymeric CellCoTec constructs in 6 mm cartilage defects, however, BioGlue^®showed significantly higher adhesive power. In vitro chondrogenesis of MSC under GDF-5 treatment resulted in equal GAG deposition and COLIIa1 and ACAN gene expression compared to controls. Importantly, significantly increased ALP-activity under treatment with GDF-5 on day 28 indicated enhanced hypertrophic differentiation compared to controls. In vivo, MSC-fibrin constructs pre-cultured with GDF-5 developed a significantly higher bone volume on day 14 and 28 compared to controls. When pre-cultured with GDF-5 constructs showed furthermore a significantly higher bone compactness (bone surface/bone volume coefficient) than controls, and thus revealed a higher maturity of the formed bone at 2 weeks and 4 weeks. Orthotopic biocompatibility testing in minipigs showed good defect filling and no adverse reactions of the subchondral bone plate for defects treated with GDF-5-augmented fibrin glue. Defects treated with BioGlue^®, however, showed considerable subchondral bone lysis.

Thus, BioGlue^®– despite its adhesive strength – should not be used for construct fixation in cartilage defects. GDF-5-augmented fibrin glue is considered promising, because of a combination of the adhesive strength of fibrin with an enhanced osteochondral activity of GDF-5 on MSC. Next step is to perform a large animal study to unravel whether GDF-5 stimulated endochondral ossification can improve scaffold integration in an orthotopic cartilage defect model.