不同表面处理方法在纳米混合树脂复合材料修复中的应用

doi:10.19439/j.sjos.2020.06.006

上海口腔医学 ›› 2020, Vol. 29 ›› Issue (6): 591-595.doi: 10.19439/j.sjos.2020.06.006

不同表面处理方法在纳米混合树脂复合材料修复中的应用

李苑荟¹, 邢孔才², 王怡婷¹, 陶巍³, 杨超⁴

1.海口市第三人民医院口腔科,海南海口 571100;
2.海南省人民医院口腔科,海南海口 570311;
3.海南医学院第一附属医院口腔科,海南海口 570100;
4.华西口腔医院口腔科,四川成都 610044

收稿日期:2020-05-26 修回日期:2020-07-07 出版日期:2020-12-25 发布日期:2021-01-08
通讯作者: 邢孔才,E-mail：1931197433@qq.com
作者简介:李苑荟（1984-）,女,本科,主治医师,E-mail：chang1yhua@163.com
基金资助:
海南省自然科学基金 (817372)

Application of different surface treatment methods in teeth restoration with nano composite resin

LI Yuan-hui¹, XING Kong-cai², WANG Yi-ting¹, TAO Wei³, YANG Chao⁴

1. Department of Stomatology,Haikou Third People's Hospital.Haikou 571100, Hainan Province;
2. Department of Stomatology, Hainan People's Hospital.Haikou 570311,Hannan Province;
3. Department of Stomatology, The First Affiliated Hospital of Hainan Medical College.Haikou 570100,Hannan Province;
4. Department of Stomatology, West China Dental Hospital. Chengdou 610044, Sichuan Province, China

Received:2020-05-26 Revised:2020-07-07 Online:2020-12-25 Published:2021-01-08

摘要/Abstract

摘要： 目的： 分析不同表面处理方法和粘接剂自酸蚀功能单体对树脂-复合材料界面即时修复粘结强度和完整性的影响。方法： 采用纳米树脂复合材料制作98个树脂复合材料,随机分为A1、A2、B1、B2、C、D组,各14个试件。表面未处理的试件作为阳性对照组（14个试件）。A1组用Gluma 通用粘接剂系统抛光,A2组用Gluma 通用粘接剂系统抛光、喷砂,B1组用Tokuyama Bond ForceⅡ^TM粘结系统抛光,B2组用Tokuyama Bond ForceⅡ^TM抛光、喷砂,C组仅经抛光样品组。D组仅做喷砂。采用与底物相同的树脂复合材料,对修复后试件进行剪切粘结强度（shear bond strength,SBS）测试,所有样本均进行电子显微镜扫描、测定表面轮廓,进行失效分析。采用SPSS 20.0软件包对数据进行统计学处理。结果： D组修复粘结强度显著高于阴性对照组（P<0.05）,A1、A2、B2、B1组粘结强度显著高于C、D组（P<0.05）;B1、D或A1组相比,粘结强度无显著差异（P>0.05）;B2组、阳性对照组粘结强度无显著差异（P>0.05）。除喷砂、TBFⅡ外,阳性对照组粘合强度值显著高于A1、C组（P<0.05）。抛光后表面粘合失效率高于喷砂样本（P<0.05）;抛光、Gluma处理样品粘合失败率高于抛光、TBFⅡ处理样品（P<0.05）;喷砂、TBFⅡ处理的表面内聚破坏率高于抛光、TBFⅡ处理（P<0.05）。抛光技术的表面粗糙度与喷砂技术相比,较规则且粗糙度较低（P<0.05）。结论： 经喷砂处理的复合材料基材加TBFⅡ,其修复粘结性最强,且表面内聚破坏率较高,TBFⅡ处理粘合失败率低。但经喷砂处理后的材料易堆积食物残渣,而抛光后的材料则不易发生。使用喷砂处理的复合材料基材上加TBFⅡ的患者,需正确有效地维护口腔卫生。

关键词: 表面处理, 粘接剂自酸蚀功能单体, 树脂-复合材料界面, 即时修复粘结强度, 完整性

Abstract: PURPOSE: To investigate the effects of different surface treatments and adhesive self-etch functional monomers on the immediate repair bond strength and integrity of the repaired resin composite interface. METHODS: Ninety-eight resin composite blocks made of a nanohybrid resin composite were randomly divided into seven groups, each with 14 blocks, including positive control group: non-conditioned surface, Group A1: Gluma Comfort Bond, Group A2: Gluma Comfort Bond and sandblasting, Group B1: Tokuyama Bond Force II^TM adhesive system, Group B2: Tokuyama Bond Force II^TM adhesive system and sandblasting, Group C: polishing, and Group D: sandblasting. Resin composite identical to the substrate was applied and the repaired specimens were subjected to shear bond strength (SBS) testing. Representative samples from all groups received scanning electron microscopy and surface profilometry to determine their mode of failure. The data were processed with SPSS 20.0 software package. RESULTS: SBS of Group D was significantly higher than that of positive control group (P<0.05). SBS of Group A1, A2, B1 and B2 was significantly higher than that of Group C and D (P<0.05). Comparison of SBS among Group B1, D and A1 showed no significant difference(P>0.05). SBS between Group B2 and positive control group had no significant difference(P>0.05). Except specimens with sandblasting and the use of TBF II system, SBS of positive control group was significantly higher than that of Group A1 and C(P<0.05). The polished specimens had significantly more adhesive failures than those with sandblasted surfaces (P<0.05). Specimens treated with polishing and Gluma Comfort Bond showed significantly more adhesive failures than those treated with polishing and TBF II system (P<0.05). The sandblasted surfaces conditioned with TBF II showed significantly more cohesive failures than those treated with polishing and TBF II (P<0.05). The sandblasted specimens provided significantly more irregular and rougher surface finish than the polishing technique (P<0.05). CONCLUSIONS: Sandblasting of the composite substrate and the use of TBF II adhesive system shows the highest repair bond strength, higher adhesive interfacial failures and fewer cohesive failures; however, it is noteworthy that the composite substrate types yield statistically higher food residue rate, which results in poor oral hygiene maintenance. Therefore, the application of this repair protocol should match up with correct oral health behaviors.

Key words: Surface treatments, Self etching functional monomer of binder, Resin composite interface, Immediate repair bond strength, Integrity

中图分类号:

R783.1

李苑荟, 邢孔才, 王怡婷, 陶巍, 杨超. 不同表面处理方法在纳米混合树脂复合材料修复中的应用[J]. 上海口腔医学, 2020, 29(6): 591-595.

LI Yuan-hui, XING Kong-cai, WANG Yi-ting, TAO Wei, YANG Chao. Application of different surface treatment methods in teeth restoration with nano composite resin[J]. Shanghai Journal of Stomatology, 2020, 29(6): 591-595.

参考文献

[1] Khan A, Kheraif A, Jamaluddin S, et al.Recent trends in surface treatment methods for bonding composite cement to zirconia: a reveiw[J]. J Adhes Dent, 2017, 19(1): 7-19.
[2] 苗春卉, 翟全胜, 张晨乾, 等. 表面处理对石英纤维增强PAA树脂复合材料界面性能的影响[J]. 玻璃钢/复合材料, 2019, 10(7): 135-137.
[3] 肖春平, 万里鹰, 张崇印, 等. 环氧树脂-脲醛树脂@2-甲基咪唑微胶囊/环氧树脂复合材料的制备及自修复性能[J]. 复合材料学报, 2019, 36(9): 2013-2022.
[4] 冯古雨, 曹海建, 周洪涛, 等. 预固化工艺对玻璃纤维/环氧树脂复合材料界面及弯曲性能影响[J]. 化工新型材料, 2017, 45(11): 66-68, 72.
[5] 王志平, 孙凌丰, 路鹏程, 等. 电热作用对碳纤维/树脂复合材料界面应力的影响电热作用对碳纤维/树脂复合材料界面应力的影响[J]. 复合材料学报, 2019, 36(6): 1381-1388.
[6] Angeloni V, Mazzoni A, Marchesi G, et al.Role of chlorhexidine on long-term bond strength of self-adhesive composite cements to intraradicular dentin[J]. J Adhes Dent, 2017, 19(4): 341-348.
[7] 张伦亮, 万里鹰. 纳米SiO₂对环氧树脂微胶囊填充型自修复材料的性能影响[J]. 工程塑料应用, 2019, 20(8): 228-230.
[8] Rohr N, Flury A, Fischer J.Efficacy of a universal adhesive in the bond strength of composite cements to polymer-infiltrated ceramic[J]. J Adhes Dent, 2017, 19(5): 417-424.
[9] Amiri E, Balouch F, Atri F.Effect of self-adhesive and separate Etch adhesive dual cure resin cements on the bond strength of fiber post to dentin at different darts of the root[J]. J Dent (Tehran), 2017, 14(3): 153-158.
[10] 丁祥彬, 罗梦, 路广遥, 等. 不同表面处理对316L钢焊缝耐液态铅铋腐蚀的影响[J]. 焊接, 2019,16(2): 21-25.
[11] 倪爱清, 朱坤坤, 王继辉. 纳米SiO-NaOH-有机硅烷偶联剂表面改性对苎麻纤维/乙烯基酯树脂复合材料性能的影响[J]. 复合材料学报, 2019, 36(11): 2579-2586.
[12] Stape T, Leo T, Abuna G, et al.Optimization of the etch-and-rinse technique: new perspectives to improve resin-dentin bonding and hybrid layer integrity by reducing residual water using dimethyl sulfoxide pretreatments[J]. Dent Mater, 2018, 34(7): 967-977.
[13] Wang Z, Cao N, He J, et al.Mechanical and anticorrosion properties of furan/epoxy-based basalt fiber-reinforced composites[J]. J Appl Pol Sci, 2017, 134(19): 381-383.
[14] 马少华, 费昺强, 许良, 等. 热氧老化对碳纤维双马树脂基复合材料性能的影响[J]. 材料工程, 2017, 45(12): 50-57.
[15] Nejat A, Lee J, Shah S, et al.Retention of CAD/CAM resin composite crowns following different bonding protocols[J]. Am J Dent, 2018, 31(2): 97-102.

不同表面处理方法在纳米混合树脂复合材料修复中的应用

Application of different surface treatment methods in teeth restoration with nano composite resin

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