Targeted Antimicrobial Self-assembly Peptide Hydrogel with in Situ Bio-mimic Remineralization for Caries Management

Overview

Journal Bioact Mater

Specialty Biomedical Engineering

Date 2024 Nov 13

PMID 39534787

Authors

Li Zhou

Qing Liu

Zehui Fang

Quan Li Li

Hai Ming Wong

Affiliations

Soon will be listed here.

Abstract

The single-function agents with wide-spectrum activity which tend to disturb the ecological balance of oral cavity cannot satisfy dental treatment need. A multi-functional agent with specifically targeted killing property and in situ remineralization is warranted for caries management. A novel multi-functional agent (8DSS-C8-P-113) consisting of three domains, i.e., a non-specific antimicrobial peptide (AMP) (P-113), a competence stimulating peptide (C8), and an enhancing remineralization domain (8DSS), is fabricated and evaluated in this study. The findings demonstrates that 2 μM mL of 8DSS-C8-P-113 eliminates planktonic () without disrupting the oral normal flora. At a concentration of 8 μM mL, it exhibits the ability to prevent ans' adhesion. Furthermore, 8DSS-C8-P-113 self-assembles a hydrogel state at the higher concentration of 16 μM mL. This hydrogel self-adheres on the tooth surface, resisting acid attack, eradicating biofilm, and inducing mineralization in order to facilitate the repair of demineralized dental hard tissue. Its significant effectiveness in reducing the severity of dental caries is also demonstrated in vivo in a rat model. This study suggests that the multi-functional bioactive AMP 8DSS-C8-P-113 is a promising agent to specifically target pathogen, prevent tooth demineralization, and effectively induce in situ bio-mimic remineralization for the management of dental caries.

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