Almiro Matilde, Marinho Beatriz, Delgado António H S, Rua João, Monteiro Paulo, Santos Inês Caetano, Proença Luís, Mendes José João, Gresnigt Marco M M
Department of Conservative Dentistry, Instituto Universitário Egas Moniz (IUEM), Monte de Caparica, 2829-511 Almada, Portugal.
Centro de Investigação Interdisciplinar Egas Moniz (CiiEM), Instituto Universitário Egas Moniz (IUEM), Monte de Caparica, 2829-511 Almada, Portugal.
Materials (Basel). 2022 Mar 10;15(6):2045. doi: 10.3390/ma15062045.
There is still a lack of consensus concerning the recommended etching concentration, application time and type of silane when bonding lithium disilicate-reinforced glass ceramics manufactured by CAD/CAM. The purpose of this study was thus to conduct an in vitro study which investigates the influence of hydrofluoric acid (HF) concentration, etching time and silane type on the microtensile bond strength (μTBS) of lithium disilicate to resin composites. Thirty-nine IPS e.max CAD blocks were randomly divided between thirteen groups (n = 3). The variables were HF concentration (9.5 or 4.9%), etching time (20 or 60 s) and silane type (Bis-Silane, Monobond Plus and ESPE Sil Silane). The blocks were cut into beams, aged for 10,000 cycles in a thermocycler and submitted to tensile stress to determine μTBS. A control group featuring the Monobond Etch & Prime (MEP) agent that combines etching/silanisation into a simultaneous process was also added. This group was discarded from the analysis due to only having pre-test failures. The data were analysed using a three-way ANOVA (α = 0.05). The HF concentration, etching time and silane type significantly influenced μTBS (p < 0.001). Significant interactions between time and silane type (p = 0.004), HF concentration and silane type (p < 0.001) and among the three factors (p < 0.001) were noted. Etching lithium disilicate with 9.5% HF (60 s), followed by the application of Bis-Silane, resulted in the highest μTBS (16.6 ± 9.0 MPa). The highest concentration and etching time under study, combined with a two-part silane, resulted in the highest bond strength, while the application of MEP showed a complete pre-test failure.
在通过计算机辅助设计/计算机辅助制造(CAD/CAM)生产的二硅酸锂增强玻璃陶瓷粘结时,对于推荐的蚀刻浓度、应用时间和硅烷类型仍缺乏共识。因此,本研究的目的是进行一项体外研究,探讨氢氟酸(HF)浓度、蚀刻时间和硅烷类型对二硅酸锂与树脂复合材料的微拉伸粘结强度(μTBS)的影响。39个IPS e.max CAD块随机分为13组(n = 3)。变量为HF浓度(9.5%或4.9%)、蚀刻时间(20秒或60秒)和硅烷类型(双硅烷、单键增强剂和ESPE硅烷)。将这些块切割成梁,在热循环仪中老化10000次循环,然后施加拉伸应力以确定μTBS。还添加了一个对照组,该组使用将蚀刻/硅烷化结合为一个同步过程的单键蚀刻和底涂剂(MEP)。由于该组仅在预测试时出现失败情况,因此从分析中剔除。使用三因素方差分析(α = 0.05)对数据进行分析。HF浓度、蚀刻时间和硅烷类型对μTBS有显著影响(p < 0.001)。注意到时间和硅烷类型之间(p = 0.004)、HF浓度和硅烷类型之间(p < 0.001)以及三个因素之间(p < 0.001)存在显著交互作用。用9.5%HF蚀刻二硅酸锂(60秒),然后使用双硅烷,可得到最高的μTBS(16.6 ± 9.0 MPa)。研究中最高的浓度和蚀刻时间,与双组分硅烷相结合,产生了最高的粘结强度,而使用MEP则在预测试时完全失败。
