DMAE-CB和NACP改性牙本质粘接剂的边缘微渗漏研究

doi:10.13591/j.cnki.kqyx.2025.02.002

摘要/Abstract

摘要：

目的评价甲基丙烯酰氧乙基-正十六烷基-二甲基氯化铵(methacryloxylethyl cetyldimethyl ammonium chloride,DMAE-CB)与无定型纳米磷酸钙(nanoparticles of amorphous calcium phosphate,NACP)改性的牙本质粘接剂用于牙体缺损粘接修复经老化模拟后试件的边缘微渗漏情况。方法分别在实验室合成DMAE-CB和NACP,参考课题组前期实验分组将两种成分在粘接剂中所占的不同质量分数分为8组。A:粘接剂+3%DMAE-CB+25%NACP,B:粘接剂+4%DMAE-CB+35%NACP,C:粘接剂+1%DMAE-CB+15%NACP,D:粘接剂+4%DMAE-CB+15%NACP,E:粘接剂+1%DMAE-CB+35%NACP,F:粘接剂+3%DMAE-CB,G:粘接剂+25%NACP,H:商品粘接剂对照组。收集40颗人离体第三磨牙并随机分为8组制备标准Ⅱ类洞形,接着使用上述8组粘接剂分别制备牙体缺损Ⅱ类洞形粘接修复试件,进行冷热循环模拟老化,试件老化后使用染色剂浸泡染色。染色后的每个试件分别用低速切割机沿𬌗龈近远中向切割成4份牙体组织切片,置于体视显微镜下分别观察剖面的龈壁及𬌗面洞缘染色剂渗入深度并按统一标准记录微渗漏等级。最后,从8组试件中分别随机抽取1个切割后的粘接试件,剖面喷金后用扫描电镜观察测量树脂充填物与牙体硬组织的间隙宽度,组间微渗漏深度采用Kruskal-Wallis法进行分析,充填体与牙体组织间隙宽度采用秩和检验法进行分析,P<0.05时表示差异有统计学意义。结果渗透染色结果显示,实验组与对照组的龈壁及𬌗面洞缘边缘微渗漏深度差异均无统计学意义(P>0.05),龈壁微渗漏深度与𬌗面洞缘微渗漏深度差异有统计学意义(P<0.05);扫描电镜结果经粒径测量分析取平均值后显示:实验组与对照组的充填修复体与牙体硬组织间隙差异无统计学意义(P>0.05)。结论经DMAE-CB和NACP改性的牙本质粘接剂在增加了抗菌性及再矿化性的同时不影响粘接修复的边缘微渗漏,为其在临床应用提供了可靠的理论依据。

关键词: 微渗漏, 冷热循环测试, 牙本质粘接剂, 甲基丙烯酰氧乙基-正十六烷基-二甲基氯化铵, 无定型纳米磷酸钙

Abstract:

Objective To assess the marginal microleakage of specimens following aging simulation of adhesive restorations for dental defects using methacryloxylethyl cetyldimethyl ammonium chloride (DMAE-CB)and nanoparticles of amorphous calcium phosphate (NACP) binder. Methods DMAE-CB and NACP were synthesized in the laboratory. Eight groups were formed by varying the mass fraction ratios of the two components in the adhesive according to previous experiments, A: binder + 3% DMAE-CB + 25% NACP, B: binder + 4% DMAE-CB + 35% NACP, C: binder + 1% DMAE-CB + 15% NACP, D: binder + 4% DMAE-CB + 15% NACP, E: binder + 1% DMAE-CB + 35% NACP, F: binder + 3% DMAE-CB, G: binder + 25% NACP, H: SBMP binder as the control group. Forty human third molars were collected and randomly divided into 8 groups to prepare standardized Class Ⅱ preparations. Subsequently, dental defect adhesive restoration specimens were made by using the 8 groups of binder, and aging simulation was performed through thermal cycling. After thermal cycling, the specimens were immersed in the dye solution. Each specimen was sectioned into 4 parts of dentin tissue slices along the gingival, proximal, and occlusal walls using a low-speed cutting machine, and the depth of dye penetration was observed under a stereomicroscope and recorded according to a unified standard for microleakage level. Finally, one randomly selected adhesive specimen from each of the 8 groups was subjected to gold sputtering and observed under scanning electron microscopy (SEM) to measure the gap width between the resin and dental tissue. Results Penetration staining showed that there were no statistically significant differences in the depth of marginal microleakage between the experimental and control groups on the gingival and occlusal walls (P>0.05). However, there was a statistically significant difference in microleakage depth between the gingival and occlusal walls (P<0.05). Scanning electron microscopy (SEM) results, after averaging particle size measurements, revealed no statistically significant differences in the gap width between the filling restorations and dental hard tissues between the experimental and control groups (P>0.05). Conclusion Dentin adhesives modified with DMAE-CB and NACP increase antibacterial and remineralization properties without affecting marginal microleakage in adhesive restorations, providing reliable theoretical support for their clinical application.

Key words: microleakage, thermal cycling, dentin adhesives, methacryloxylethyl cetyldimethyl ammonium chloride, nanoparticles of amorphous calcium phosphate

中图分类号:

R783.1

李卓衡, 杨硕, 张慧楠, 高菁哲, 孙宇. DMAE-CB和NACP改性牙本质粘接剂的边缘微渗漏研究[J]. 口腔医学, 2025, 45(2): 89-94.

LI Zhuoheng, YANG Shuo, ZHANG Huinan, GAO Jingzhe, SUN Yu. Investigating marginal microleakage of dentin adhesive modified with methacryloxylethyl cetyldimethyl ammonium chloride (DMAE-CB) and nanoparticles of amorphous calcium phosphate (NACP)[J]. Stomatology, 2025, 45(2): 89-94.

图/表 5

参考文献 20

[1]	Singh S. Microleakage studies: A viewpoint[J]. J Conserv Dent, 2023, 26(1): 1-2.
[2]	张兆钰, 孙宇, 张雪, 等. DMAE-CB和NACP改性牙本质粘结剂的粘结性能和抗菌性能研究[J]. 口腔医学, 2018, 38(3): 227-229, 272.
[3]	刘娟, 孙宇, 修朝博, 等. NACP和DMAE-CB改性牙本质黏结剂的黏结性能和再矿化性能研究[J]. 哈尔滨医科大学学报, 2023, 57(6): 605-609.
[4]	Zhang X, Li YQ, Sun XX, et al. Biomimetic remineralization of demineralized enamel with nano-complexes of phosphorylated chitosan and amorphous calcium phosphate[J]. J Mater Sci Mater Med, 2014, 25(12): 2619-2628.
[5]	Nishi N, Maekita Y, Nishimura SI, et al. Highly phosphorylated derivatives of chitin, partially deacetylated chitin and chitosan as new functional polymers: Metal binding property of the insolubilized materials[J]. Int J Biol Macromol, 1987, 9(2): 109-114.
[6]	陈吉华, 肖玉鸿, 李芳, 等. 季铵盐抗菌单体改性牙本质粘接剂的抗菌性能研究[J]. 北京口腔医学, 2010, 18(4): 181-184.
[7]	方玉叶, 吕长海. 微渗漏检测方法的研究进展[J]. 医学综述, 2019, 25(11): 2242-2247.
[8]	符从仪, 朱来宽. 树脂直接修复粘接剂成分及性能的研究进展[J]. 临床口腔医学杂志, 2024, 40(1): 50-54.
[9]	Perdigão J. Current perspectives on dental adhesion: (1) Dentin adhesion-not there yet[J]. Jpn Dent Sci Rev, 2020, 56(1): 190-207.
[10]	Cayo-Rojas CF, Hernández-Caba KK, Aliaga-Mariñas AS, et al. Microleakage in Class Ⅱ restorations of two bulk fill resin composites and a conventional nanohybrid resin composite: An in vitro study at 10, 000 thermocycles[J]. BMC Oral Health, 2021, 21(1): 619. doi: 10.1186/s12903-021-01942-0 pmid: 34861859
[11]	Tay FR, Pashley DH, Hiraishi N, et al. Tubular occlusion prevents water-treeing and through-and-through fluid movement in a single-bottle, one-step self-etch adhesive model[J]. J Dent Res, 2005, 84(10): 891-896. pmid: 16183786
[12]	Behery H, El-Mowafy O, El-Badrawy W, et al. Gingival microleakage of Class Ⅱ bulk-fill composite resin restorations[J]. Dent Med Probl, 2018, 55(4): 383-388.
[13]	Lewis NV, Aggarwal S, Borse NN, et al. The effect of matrix metalloproteinase inhibitors on the microtensile bond strength of dentin bonding agents in caries affected dentin: A systematic review[J]. J Int Soc Prev Community Dent, 2023, 13(3): 173-184. doi: 10.4103/jispcd.JISPCD_5_23 pmid: 37564167
[14]	Liu N, Li F, Chen YJ, et al. The inhibitory effect of a polymerisable cationic monomer on functional matrix metalloproteinases[J]. J Dent, 2013, 41(11): 1101-1108. doi: 10.1016/j.jdent.2013.08.008 pmid: 23954575
[15]	Agarwal A, Simonaitis J, Goyal VK, et al. Secondary electron count imaging in SEM[J]. Ultramicroscopy, 2023, 245: 113662.
[16]	Lui JL, Masutani S, Setcos JC, et al. Margin quality and microleakage of Class Ⅱ composite resin restorations[J]. J Am Dent Assoc, 1987, 114(1): 49-54. pmid: 3468167
[17]	边媛媛, 雷建锋, 侯静怡, 等. 182颗恒牙邻面牙釉质厚度的测量研究[J]. 中华口腔医学杂志, 2020, 55(7): 488-493.
[18]	高岩. 口腔组织病理学[M]. 8版. 北京: 人民卫生出版社, 2020.
[19]	Guo J, Wang LP, Zhu J, et al. Impact of dentinal tubule orientation on dentin bond strength[J]. Curr Med Sci, 2018, 38(4): 721-726. doi: 10.1007/s11596-018-1936-8 pmid: 30128884
[20]	Cadenaro M, Josic U, Maravić T, et al. Progress in dental adhesive materials[J]. J Dent Res, 2023, 102(3): 254-262.