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Abstract

The major goal in restorative dentistry is to develop a true regenerative approach that fully recovers hydroxyapatite crystals within the caries lesion. Recently, a rationally designed self-assembling peptide P₁₁-4 (Ace-QQRFEWEFEQQ-NH₂) has been developed to enhance remineralization on initial caries lesions, yet its applicability on dentin tissues remains unclear. Thus, the present study investigated the interaction of P₁₁-4 with the organic dentin components as well as the effect of P₁₁-4 on the proteolytic activity, mechanical properties of the bonding interface, and nanoleakage evaluation to artificial caries-affected dentin. Surface plasmon resonance and atomic force microscopy indicated that P₁₁-4 binds to collagen type I fibers, increasing their width from 214 ± 4 nm to 308 ± 5 nm (P < 0.0001). P₁₁-4 also increased the resistance of collagen type I fibers against the proteolytic activity of collagenases. The immediate treatment of artificial caries-affected dentin with P₁₁-4 enhanced the microtensile bonding strength of the bonding interface (P < 0.0001), reaching values close to sound dentin and decreasing the proteolytic activity at the hybrid layer; however, such effects decreased after 6 mo of water storage (P < 0.05). In conclusion, P₁₁-4 interacts with collagen type I, increasing the resistance of collagen fibers to proteolysis, and improves stability of the hybrid layer formed by artificial caries-affected dentin.

Keywords

operative dentristry biomaterials protease inhibitors tissue engineering caries

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The Self-Assembling Peptide P 11 -4 Prevents Collagen Proteolysis in Dentin

Abstract

Keywords

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Supplementary Material