Influence of ß-tricalcium phosphate granule size and morphology on tissue reaction in vivo.

In this study the tissue reaction to five different ß-tricalcium phosphate (ß-TCP)-based bone substitute materials differing only in size, shape and porosity was analyzed over 60 days, at 3, 10, 15, 30 and 60 days after implantation. Using the subcutaneous implantation model in Wistar rats both the inflammatory response within the implantation bed and the resulting vascularization of the biomaterials were qualitatively and quantitatively assessed by means of standard and special histological staining methods. The data from this study showed that all investigated ß-TCP bone substitutes induced the formation of multinucleated giant cells. Changes in size, shape and porosity influenced the integration of the biomaterials within the implantation bed and the formation of tartrate-resistant acid phosphatase (TRAP)-positive and TRAP-negative multinucleated giant cells, as well as the rate of vascularization. While a high porosity generally allowed cell and fiber in-growth within the center of the bone substitute, a lower porosity resulted in a mosaic-like integration of the materials, with the granules serving as place holders. The number of multinucleated giant cells located in the implantation bed positively correlated with the vascularization rate. These data emphasize that all biomaterials investigated were capable of inducing the formation of TRAP-positive multinucleated giant cells as a sign of biomaterial stability. Furthermore, these cells directly influenced vascularization by secretion of vascular endothelial growth factor (VEGF), as well as other chemokines. Based on these findings, the role of multinucleated giant cells in the foreign body reaction to biomaterials might need to be reconsidered. This study demonstrates that variations in the physical properties of a bone substitute material clearly influence the (extent of the) inflammatory reaction and its consequences.

Dynamic in vivo biocompatibility of angiogenic peptide amphiphile nanofibers.

Biomaterials that promote angiogenesis have great potential in regenerative medicine for rapid revascularization of damaged tissue, survival of transplanted cells, and healing of chronic wounds. Supramolecular nanofibers formed by self-assembly of a heparin-binding peptide amphiphile and heparan sulfate-like glycosaminoglycans were evaluated here using a dorsal skinfold chamber model to dynamically monitor the interaction between the nanofiber gel and the microcirculation, representing a novel application of this model. We paired this model with a conventional subcutaneous implantation model for static histological assessment of the interactions between the gel and host tissue. In the static analysis, the heparan sulfate-containing nanofiber gels were found to persist in the tissue for up to 30 days and revealed excellent biocompatibility. Strikingly, as the nanofiber gel biodegraded, we observed the formation of a de novo vascularized connective tissue. In the dynamic experiments using the dorsal skinfold chamber, the material again demonstrated good biocompatibility, with minimal dilation of the microcirculation and only a few adherent leukocytes, monitored through intravital fluorescence microscopy. The new application of the dorsal skinfold model corroborated our findings from the traditional static histology, demonstrating the potential use of this technique to dynamically evaluate the biocompatibility of materials. The observed biocompatibility and development of new vascularized tissue using both techniques demonstrates the potential of these angiogenesis-promoting materials for a host of regenerative strategies.