School of Dentistry, University of Missouri-Kansas City, 650E 25th St, Kansas City, MO, 64108, USA.
University Ceuma, Rua Josué Montello n° 1, Renascença II, São Luís, Maranhão, 65075-120, Brazil.
Clin Oral Investig. 2021 Jun;25(6):3543-3553. doi: 10.1007/s00784-020-03677-8. Epub 2020 Nov 16.
This study investigated the ability of modified phosphoric acids containing chlorhexidine (CHX) or grape seed extract (GSE) for promoting simultaneous biomodification during acid etching on bonding properties in caries-affected dentin (CAD).
Thirty-two human molars (8 with sound dentin [SD] and 24 naturally CAD) were selected for the study. The SD and CAD were initially exposed, then randomized and etched according to the following groups: (1) SD (SD-CT) and CAD (CAD-CT) both with 37% phosphoric acid, (2) CAD with 2% CHX containing 37% phosphoric acid (CAD-CHX), and (3) CAD with 2% GSE containing 10% phosphoric acid (CAD-GSE). The bonding procedure and composite build-ups were performed after acid etching. Subsequently, they were sectioned in resin-dentin specimens. The specimens were submitted for chemical profiling by micro-Raman, microtensile bond strength (μTBS), failure mode with chemical characterization by FEG/SEM-EDX, and in situ zymography by CLSM. The data from μTBS and CLSM were statistically analyzed (1-way ANOVA and Tukey's test; α = 0.05).
The highest μTBS results were shown for SD-CT in comparison with all CAD groups (p < 0.001), and the lowest for CAD-CT and CAD-CHX (p < 0.001). The etching with CHX did not increase the μTBS for CAD when compared with CT (p = 0.52). However, the etching with GSE improved significantly the μTBS for CAD when compared with CT and CHX (p < 0.001). The chemical profile detected chemical and structural changes in collagen peaks for CAD-CT, which were not detected when the CAD was etched by modified acids. Also, the poorest hybridization ability was detected in CAD for CT, which was significantly improved with modified acids, especially the GSE, as evaluated by chemical profile and failure mode. A significant reduction of MMP activity on CAD was promoted by modified acids in comparison with CT (both p < 0.001).
The GSE-containing acid was able to promote biomodification during the acid etching, increasing the bonding properties and reducing the activity of the MMPs within the hybrid layer.
The use of GSE-containing phosphoric acid can be a promising alternative to improve the bonding performance on caries-affected dentin, since it is capable of biomodifying the dentin during the acid etching, without adding any extra step in bonding procedures.
本研究旨在探讨含有洗必泰(CHX)或葡萄籽提取物(GSE)的改性磷酸在酸蚀过程中促进牙本质(CAD)同时生物改性的能力。
选择 32 个人类磨牙(8 个有正常牙本质[SD]和 24 个自然 CAD)进行研究。SD 和 CAD 最初暴露,然后根据以下组随机化和酸蚀:(1)SD(SD-CT)和 CAD(CAD-CT)均为 37%磷酸,(2)CAD 为 2%CHX 含 37%磷酸(CAD-CHX),(3)CAD 含 10%磷酸的 2%GSE(CAD-GSE)。酸蚀后进行粘结程序和复合堆积。随后,将它们在树脂-牙本质标本中进行切割。用微拉曼光谱法、微拉伸粘结强度(μTBS)、通过 FEG/SEM-EDX 进行化学特征的失效模式、以及通过 CLSM 进行原位酶谱法对标本进行化学特征分析。通过单因素方差分析和 Tukey 检验对 μTBS 和 CLSM 数据进行统计学分析(α=0.05)。
与所有 CAD 组相比,SD-CT 的 μTBS 结果最高(p<0.001),而 CAD-CT 和 CAD-CHX 的结果最低(p<0.001)。与 CT 相比,CHX 酸蚀并未增加 CAD 的 μTBS(p=0.52)。然而,与 CT 和 CHX 相比,GSE 酸蚀显著提高了 CAD 的 μTBS(p<0.001)。化学图谱检测到 CAD-CT 中胶原峰的化学和结构变化,但在使用改性酸蚀时未检测到。同样,在 CT 中,CAD 的杂交能力最差,而在改性酸的作用下,尤其是 GSE 的作用下,这种能力得到了显著改善,这可以通过化学图谱和失效模式来评估。与 CT 相比,改性酸在 CAD 中显著降低了 MMP 活性(均 p<0.001)。
含有 GSE 的酸能够在酸蚀过程中促进生物改性,从而提高粘结性能并降低混合层中 MMP 的活性。
使用含 GSE 的磷酸可以作为一种有前途的替代方法,以改善对受龋牙本质的粘结性能,因为它能够在酸蚀过程中对牙本质进行生物改性,而无需在粘结程序中添加任何额外步骤。
