Cyclic mechanical compression increases mineralization of cell-seeded polymer scaffolds in vivo.

Despite considerable documentation of the ability of normal bone to adapt to its mechanical environment, very little is known about the response of bone grafts or their substitutes to mechanical loading even though many bone defects are located in load-bearing sites. The goal of this research was to quantify the effects of controlled in vivo mechanical stimulation on the mineralization of a tissue-engineered bone replacement and identify the tissue level stresses and strains associated with the applied loading. A novel subcutaneous implant system was designed capable of intermittent cyclic compression of tissue-engineered constructs in vivo. Mesenchymal stem cell-seeded polymeric scaffolds with 8 weeks of in vitro preculture were placed within the loading system and implanted subcutaneously in male Fisher rats. Constructs were subjected to 2 weeks of loading (3 treatments per week for 30 min each, 13.3 N at 1 Hz) and harvested after 6 weeks of in vivo growth for histological examination and quantification of mineral content. Mineralization significantly increased by approximately threefold in the loaded constructs. The finite element method was used to predict tissue level stresses and strains within the construct resulting from the applied in vivo load. The largest principal strains in the polymer were distributed about a modal value of -0.24% with strains in the interstitial space being about five times greater. Von Mises stresses in the polymer were distributed about a modal value of 1.6 MPa, while stresses in the interstitial tissue were about three orders of magnitude smaller. This research demonstrates the ability of controlled in vivo mechanical stimulation to enhance mineralized matrix production on a polymeric scaffold seeded with osteogenic cells and suggests that interactions with the local mechanical environment should be considered in the design of constructs for functional bone repair.

Bone formation on tissue-engineered cartilage constructs in vivo: effects of chondrocyte viability and mechanical loading.

Interactions between bone and cartilage formation are critical during growth and fracture healing and may influence the functional integration of osteochondral repair constructs. In this study, the ability of tissue-engineered cartilage constructs to support bone formation under controlled mechanical loading conditions was evaluated using a lapine hydraulic bone chamber model. Articular chondrocytes were seeded onto polymer disks, cultured for 4 weeks in vitro, and then transferred to empty bone chambers previously implanted into rabbit femoral metaphyses. The effects of chondrocyte viability within the implanted constructs and in vivo mechanical loading on bone formation were tested in separate experiments. After 4 weeks in vivo, biopsies from the chambers consisted of a complex composite of bone, cartilage, and fibrous tissue, with bone forming in direct apposition to the cartilage constructs. Microcomputed tomography imaging of the chamber biopsies revealed that the implantation of viable constructs nearly doubled the bone volume fraction of the chamber tissue from 0.9 to 1.6% as compared with the implantation of devitalized constructs in contralateral control chambers. The application of an intermittent cyclic mechanical load was found to increase the bone volume fraction of the chamber tissue from 0.4 to 3.6% as compared with no-load control biopsies. The results of these experiments demonstrate that tissue-engineered cartilage constructs implanted into a well-vascularized bone defect will support direct appositional bone formation and that bone formation is significantly influenced by the viability of chondrocytes within the constructs and the local mechanical environment in vivo.