Mechanical characterization of self-assembling peptide hydrogels by microindentation.

Hydrogels formed from self-assembling synthetic oligopeptides have been studied for almost 2 decades for use in tissue engineering and drug delivery. Although a great deal has been learned about the microstructure of these materials, there remain questions about how peptide filaments are ordered to form a gel. These unanswered questions leave a disconnect between our understanding of the observed nanoscale mechanical properties of peptide filaments and the macroscale properties of the gels they constitute.

Elastic deformation and failure in protein filament bundles: Atomistic simulations and coarse-grained modeling.

The synthetic peptide RAD16-II has shown promise in tissue engineering and drug delivery. It has been studied as a vehicle for cell delivery and controlled release of IGF-1 to repair infarcted cardiac tissue, and as a scaffold to promote capillary formation for an in vitro model of angiogenesis. The structure of RAD16-II is hierarchical, with monomers forming long beta-sheets that pair together to form filaments; filaments form bundles approximately 30-60 nm in diameter; branching networks of filament bundles form macroscopic gels.