1. Engineering human cell-based, functionally integrated osteochondral grafts by biological bonding of engineered cartilage tissues to bony scaffolds
- Author
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Dirk J. Schaefer, Victor Valderrabano, Francine Wolf, Andrea Barbero, Christian Candrian, Vivienne Bürgin, Dieter Wirz, Ivan Martin, Celeste Scotti, Alma U. Daniels, and Marcel Jakob
- Subjects
Adult ,Cartilage, Articular ,Male ,Bone sialoprotein ,Scaffold ,Materials science ,Cell Culture Techniques ,Biophysics ,Transplants ,Bioengineering ,Bone and Bones ,Fibrin ,Cartilage tissue engineering ,Chondrocyte ,Biomaterials ,Extracellular matrix ,Osseointegration ,Materials Testing ,medicine ,Humans ,Collagen Type II ,Cells, Cultured ,Aged ,Aged, 80 and over ,Tissue Engineering ,Tissue Scaffolds ,biology ,Reproducibility of Results ,Middle Aged ,Human cell ,Coculture Techniques ,medicine.anatomical_structure ,Mechanics of Materials ,Engineered cartilage ,Ceramics and Composites ,biology.protein ,Female ,Biomedical engineering - Abstract
In this study, we aimed at developing and validating a technique for the engineering of osteochondral grafts based on the biological bonding of a chondral layer with a bony scaffold by cell-laid extracellular matrix. Osteochondral composites were generated by combining collagen-based matrices (Chondro-Gide) containing human chondrocytes with devitalized spongiosa cylinders (Tutobone) using a fibrin gel (Tisseel). We demonstrate that separate pre-culture of the chondral layer for 3 days prior to the generation of the composite allows for (i) more efficient cartilaginous matrix accumulation than no pre-culture, as assessed histologically and biochemically, and (ii) superior biological bonding to the bony scaffold than 14 days of pre-culture, as assessed using a peel-off mechanical test, developed to measure integration of bilayered materials. The presence of the bony scaffold induced an upregulation in the infiltrated cells of the osteoblast-related gene bone sialoprotein, indicative of the establishment of a gradient of cell phenotypes, but did not affect per se the quality of the cartilaginous matrix in the chondral layer. The described strategy to generate osteochondral plugs is simple to be implemented and--since it is based on clinically compliant cells and materials--is amenable to be readily tested in the clinic.
- Published
- 2010
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