Int J Stomatol

Int J Stomatol ›› 2025, Vol. 52 ›› Issue (6): 722-729.doi: 10.7518/gjkq.2025092

• Cariology and Endodontics • Previous Articles     Next Articles

Research progress of acid-base resistant zone for dental hard tissue bonding interface

Ruizhen Chen(),Xing Jiang,Jiyuan Shen,Ling Lin,Zhiqiang Zheng,Jie Lin()   

  1. Dept. of VIP Dental Service, School and Hospital of Stomatology, Fujian Medical University, Fuzhou 350002, China
  • Received:2024-08-16 Revised:2024-10-04 Online:2025-11-01 Published:2025-10-23
  • Contact: Jie Lin E-mail:crzzwddka@163.com;linjie.dds@gmail.com
  • Supported by:
    Natural Science Foundation of Fujian Province(2023J01701)

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Abstract:

Observation by scanning electron microscopy confirmed the existence of an acid-base resistant zone (ABRZ) beneath the hybrid layer at the dental bonding interface. The formation of this zone is related to the chemical reaction between acidic functional monomers and hydroxyapatite in dentin. Unlike the traditional hybrid layer, ABRZ is characterized by resin-encapsulated partially demineralized hydroxyapatite. This formation enhances the resistance of the bond interface to acid-base degradation and long-term bonding durability. Recent studies suggest that ABRZ forms more readily in self-etch adhesive systems. The structure of this zone is closely related to the chemical composition of the adhesive. In this review, the microstructure, influencing factors, and formation mechanism of ABRZ are summarized to provide insights for clinical and scientific research on dental bonding.

Key words: dental adhesion, acid-base resistant zone, dentin, enamel, functional monomer, self-etching adhesive system

CLC Number: 

  • R781.05

TrendMD: 

Fig 1

Schematic of the typical ABRZ microstructure in dentin (SEM)"

Tab 1

Advantages and disadvantages of ABRZ in different adhesive systems"

粘接系统优点缺点
酸蚀-冲洗系统通过磷酸酸蚀剂预酸蚀牙釉质,增强单体渗透,促进ABRZ形成[28]用于牙本质时无法形成ABRZ[30];临床操作难度较高,可能导致邻近牙本质过度脱矿[15]
一步法自酸蚀形成薄层ABRZ[30];简化操作流程亲水性和疏水性单体的影响可降低粘接耐久性和ABRZ的形成[32];在ABRZ下方形成漏斗状缺损[30]
两步法自酸蚀形成较厚的ABRZ[10];Clearfil SE Bond作为金标准,提高粘接界面的耐酸性[11]操作流程相对复杂
实验性释氟粘接系统增加ABRZ厚度,创造高质量的ARBZ,并有效增强粘接耐久性[11];促进牙体硬组织的矿化,提高牙体的抗酸蚀能力[22]ABRZ的厚度和粘接强度受氟离子浓度的影响,需要精确控制氟的释放量[34];牙体基质的酸抵抗性增加可能会降低自酸蚀粘接系统的效果[32]
实验性含钙底涂剂增加ABRZ厚度,增加粘接界面的耐酸性,提高粘接界面耐久性和稳定性[21]需要与其他粘接剂或修复材料配合使用,增加了治疗的复杂性[21];降低早期粘接强度,特别是当与氟化物粘接剂结合使用时[21];仍需更多的临床研究来验证其长期效果和安全性

Fig 2

Morphological differences of dentin ABRZ among different adhesive systems"

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