Int J Stomatol

Int J Stomatol ›› 2025, Vol. 52 ›› Issue (5): 606-613.doi: 10.7518/gjkq.2025077

• Cariology and Endodontics • Previous Articles     Next Articles

Research progress on antibacterial-remineralizing materials for dental enamel

Axuan Chen(),Wenyu Dai,Xianglong Han()   

  1. State Key Laboratory of Oral Diseases & National Center for Stomatology & National Clinical Research Center for Oral Diseases & Dept. of Orthodontics, West China Hospital of Stomatology, Sichuan University, Chengdu 610041, China
  • Received:2025-04-09 Revised:2025-05-19 Online:2025-09-01 Published:2025-08-27
  • Contact: Xianglong Han E-mail:869427550@qq.com;xhan@scu.edu.cn
  • Supported by:
    National Postdoctoral Research Program(GZB20240483)

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Abstract:

Antibacterial-remineralizing materials have attracted extensive attention in recent years for caries prevention and treatment owing to their breakthroughs in multifunctional integration, optimized biomimetic structural design, enhanced biocompatibility, and remarkable controllability of side effects. This review summarizes the functional characteristics and mechanisms of action of antibacterial-remineralizing materials applied to dental enamel, with a systematic classification into six categories: fluoride-based materials, bioactive glass-based materials, chitosan-based composites, amelogenin derivatives and peptides, nanomaterial systems, and plant polyphenol complexes. This review aimed to provide refe-rences for clinical prevention and treatment strategies and promote further advancements in this field of bioactive materials.

Key words: dental enamel, antimicrobial, tooth remineralization

CLC Number: 

  • R318.08

TrendMD: 

Fig 1

Diagrammatic sketch of antibacterial-remineralizing materials for dental enamel: classification and mechanisms"

Tab 1

Antibacterial-remineralizing materials for dental enamel: classification and mechanisms"

类别代表材料抗菌机制再矿化机制参考文献
氟化物基材料传统无机氟化物材料NaF、SnF2氟离子破坏细胞膜、干扰细菌代谢形成氟磷灰石抗酸溶解[12-15]
新型有机氟化物材料SDF氟离子破坏细胞膜、干扰细菌代谢;银离子破坏细胞膜、抑制细菌黏附;碱性特性提高局部pH值抑制细菌代谢[22-24]
生物活性玻璃基材料45S5碱性pH值环境抑制细菌代谢释放钙磷离子形成HAP层;硅离子诱导HAP沉积[27-29]
壳聚糖基材料CSH、PCSCS的正电荷破坏细胞膜CS黏附在牙釉质表面减少酸渗透;将钙磷离子递送至病变深层促进再矿化;诱导非晶态HAP向有序晶体转化;磷酸基团螯合钙离子形成成核位点[34-38]
釉原蛋白衍生物与多肽P11-4、CS-QP5、CS-rP172、CS-LRAP抗菌肽破坏细胞膜或干扰细菌代谢模拟天然牙釉质蛋白引导HAP有序沉积[43-47]
纳米材料体系钙磷基纳米材料ACP碱性pH值环境抑制细菌代谢释放钙磷离子促进再矿化[50]

有机大分子复合

纳米材料

ACP@SF-BZC、CPP-ACPBZC抑制细菌黏附和生物膜形成稳定ACP靶向递送钙磷离子[53-54]
光/激光响应型纳米材料TiO2-HAP复合物光催化产ROS杀灭细菌;激光杀灭表层细菌HAP提供矿化模板;激光加速HAP定向生长[55-57]
植物多酚复合物TP-ACP@CMC/LYZTP破坏生物膜;LYZ水解细菌壁CMC稳定ACP,缓释再矿化[58-59]

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