Osteonectin-derived peptide increases the modulus of a bone-mimetic nanocomposite.

Many factors contribute to the toughness of bone including the presence of nano-size apatite crystals, a dense network of collagen fibers, and acidic proteins with the ability to link the mineral phase to the gelatinous collagen phase. We investigated the effect of a glutamic acid (negatively charged) peptide (Glu6), which mimics the terminal region of the osteonectin glycoprotein of bone, on the shear modulus of a synthetic hydrogel/apatite nanocomposite. One end of the synthesized peptide was functionalized with an acrylate group (Ac-Glu6) to covalently attach the peptide to the hydrogel phase of the composite matrix. When microapatite crystals (5 microm diameter) were used, addition of Ac-Glu6 peptide did not affect the modulus of the microcomposite. However, when nanoapatite crystals (100 nm diameter) were used, addition of Ac-Glu6 resulted in significant reinforcement of the shear modulus of the nanocomposite ( approximately 100% in elastic shear modulus). Furthermore, addition of Ac-Gly6 (a neutral glycine sequence) or Ac-Lys6 (a positively charged sequence) did not reinforce the nanocomposite. These results demonstrate that the reinforcement effect of the Glu6 peptide, a sequence in the terminal region of osteonectin, is modulated by the size of the apatite crystals. The findings of this work can be used to develop advanced biomimetic composites for skeletal tissue regeneration.