Triple Function of Amelogenin Peptide-Chitosan Hydrogel for Dentin Repair

Cai, J.; Moradian-Oldak, J.

doi:10.1177/00220345231198228

J Dent Res

2023

DOI: 10.1177/00220345231198228

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Triple Function of Amelogenin Peptide-Chitosan Hydrogel for Dentin Repair

J. Cai,

J. Moradian-Oldak

Abstract: Biomimetic strategies like peptide-guided collagen mineralization promise to enhance the effectiveness of dentin remineralization. We recently reported that rationally designed amelogenin-derived peptides P26 and P32 promoted apatite nucleation, mineralized collagen, and showed potential in enamel regrowth and dentin remineralization. To facilitate the clinical application of amelogenin-derived peptides and to uncover their effectiveness in repairing dentin, we have now implemented a chitosan (CS) hydrogel for… Show more

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2024

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Cited by 4 publications

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Advancements in dental hard tissue restorative materials and challenge of clinical translation

Hu,

Pang,

Yang

et al. 2024

Sci. China Mater.

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Advancements in dental hard tissue restorative materials and challenge of clinical translation

Hu,

Pang,

Yang

et al. 2024

Sci. China Mater.

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Increased Fluorohydroxyapatite across Dentin after Fluoride Iontophoresis

Ajcharanukul,

Kosakarn,

Sujjapong

et al. 2024

J Dent Res

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Due to the multiple factors contributing to dentin demineralization and hypersensitivity among individuals, the effectiveness of the available treatments in the long term remains unclear. A recent study reported a simple strategy to potentially mimic natural remineralization with increased crystallization on the enamel caries using fluoride iontophoresis. Such an effect is also ideal for accomplishing dentin biomineralization and structural strength. This study aimed to investigate structural and compositional characteristics and permeability changes after fluoride iontophoresis with different polarities, cathodal iontophoresis (CIP), anodal iontophoresis (AIP), and the control without iontophoresis for the treatment of etched dentin under simulated pulpal pressure. The 24 premolars were divided into 3 groups: CIP, AIP, and topical application of 5% sodium fluoride (NaF) for 40 s. Relative to before treatment, iontophoresis with both polarities significantly decreased the permeability with a visible increase in occluding tubules containing crystal formation and growth throughout the dentin structure and depth. The CIP not only restored the etched dentin surface into a sound condition but also reinforced the dentin across the structure and depth by the synergistic effects of remineralization, increasing crystal formation and transformation toward the more crystalline structure of fluorohydroxyapatite. Following topical treatment, X-ray diffraction analysis and Raman spectra revealed a significant reduction in the crystal size and crystallinity associated with the raised B-type carbonate substitution into the hydroxyapatite compared with that in the sound dentin. The result was the first to reveal the ideal strategy to rapidly restore the etched dentin surface into a sound condition, including reinforcing the dentin across the structure and depth by the synergistic effects of decreasing permeability, increasing crystal formation, and transformation toward the more crystalline structure of fluorohydroxyapatite using the 5% NaF applied with the DC cathode iontophoresis. The technique is noninvasive and simple and deserves further development for clinical application.

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Antimicrobial, remineralization, and infiltration: advanced strategies for interrupting dental caries

Yang,

Li,

et al. 2024

Medical Review

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Dental caries, driven by plaque biofilm, poses a major oral health challenge due to imbalance in mineralization and demineralization. The primary objective in caries management is to maintain biofilm homeostasis while facilitating the repair and regeneration of dental hard tissues, thus restoring both structural integrity and functionality of affected teeth. Though antimicrobial and remineralization approaches haven shown promise, their standalone utilization without concurrent bacterial control or rebalancing lacks an integrated strategy to effectively arrest caries progression. Furthermore, according to the principles of minimally invasive dentistry, treatment materials should exhibit high permeability to ensure optimal sealing of demineralized tooth surfaces. The concept of interrupting dental caries (IDC) has emerged as a holistic approach, drawing upon extensive research encompassing three pivotal techniques: antibacterial strategies, remineralization therapies, and infiltration mechanisms, all of which are indispensable components in combating the progression of dental caries. In this review, we provide a comprehensive overview of the mechanisms and applications of antibacterial, remineralization, and infiltration technologies within the context of caries management. Additionally, we summarize advanced materials that align with the IDC concept, aiming to offer valuable insights for designing next-generation materials adept at preventing or halting caries progression efficiently.

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Triple Function of Amelogenin Peptide-Chitosan Hydrogel for Dentin Repair

Cited by 4 publications

References 37 publications

Advancements in dental hard tissue restorative materials and challenge of clinical translation

Advancements in dental hard tissue restorative materials and challenge of clinical translation

Increased Fluorohydroxyapatite across Dentin after Fluoride Iontophoresis

Antimicrobial, remineralization, and infiltration: advanced strategies for interrupting dental caries

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