Abstract
One of the important targets in regenerative medicine is to design resorbable materials that can promote formation of new bone in large skeletal defects. One approach to this challenge is to use a bioactive and biodegradable organic matrix that can promote cellular adhesion and direct differentiation. We have here studied matrices composed of peptide amphiphiles (PAs) that self-assemble into nanofibers and create self-supporting gels under cell culture conditions. The bioactivity of PAs was designed by incorporating in their peptide sequences phosphoserine residues, to promote hydroxyapatite formation in the culture medium, and the cell adhesion epitope RGDS. In osteogenic medium supplemented with calcium the PA nanofibers were found to nucleate spheroidal nanoparticles of crystalline carbonated hydroxyapatite approximately 100 nm in diameter. This mineralization mode is not epitaxial relative to the long axis of the nanofibers and occurs in the presence of serine or phosphoserine residues in the peptide sequence of the amphiphiles. Mixing of the phosphoserine-containing PAs with 5 wt.% RGDS-containing PA molecules does not inhibit formation of the mineral nanoparticles. Quantitative real time reverse transcription polymerase chain reaction and immunohistochemistry analysis for alkaline phosphatase (ALP) and osteopontin expression suggest that these mineralized matrices promote osteogenic differentiation of human mesenchymal stem cells. Based on ALP expression, the presence of phosphoserine residues in PA nanofibers seems to favor osteogenic differentiation.