Tribst Jpm, Anami L C, Özcan M, Bottino M A, Melo R M, Saavedra Gsfa
Oper Dent. 2018 Jul/Aug;43(4):372-379. doi: 10.2341/16-348-L. Epub 2018 Mar 7.
This study tested whether a self-etching surface agent and the conventional hydrofluoric acid (HF) would provide the same bonding capacity between resin cement and feldspathic (Fd) and lithium disilicate (Ld) ceramics. Ceramic blocks were cut with a low-speed diamond saw with water cooling (Isomet 1000, Buehler, Lake Bluff, IL, USA) into 20 blocks of 5 × 7 × 4 mm, which were ground flat in a polishing machine (EcoMet/AutoMet 250, Buehler) under water cooling. The blocks were randomly divided into eight groups (n=5), according to ceramic type (Ld or Fd), surface conditioning (HF + Monobond Plus or Etch and Prime), and aging by thermocycling (TC or absence-baseline). After 24 hours in 37°C distilled water, blocks were embedded into acrylic resin and 1-mm cross-section beams composed of ceramic/cement/composite were obtained. The microtensile test was performed in a universal testing machine (DL-1000, EMIC, São José dos Campos, Brazil; 0.5 mm.min, 50 kgf load cell). Bond strength (MPa) was calculated by dividing the load at failure (in N) by the bonded area (mm). The fractured specimens were examined under stereomicroscopy, and one representative sample of each group was randomly selected before the cementation and was further used for analysis using scanning electron microscopy (SEM) and energy-dispersive x-ray spectroscopy (EDS). The self-etching agent showed the highest bond strength for Fd (24.66±4.5) and Ld (24.73±6.9) ceramics and a decrease in surface wettability. SEM and EDS showed the presence of similar components in the tested materials with different topographies for both. Therefore, the self-etching primer was able to deliver even higher bonding than HF+silane to a resin cement.
本研究测试了一种自酸蚀表面处理剂与传统氢氟酸(HF)在树脂水门汀与长石质(Fd)陶瓷和二硅酸锂(Ld)陶瓷之间是否具有相同的粘结能力。用带水冷装置的低速金刚石锯(Isomet 1000,美国伊利诺伊州莱克布拉夫市比勒公司)将陶瓷块切割成20个5×7×4 mm的小块,在水冷条件下于抛光机(EcoMet/AutoMet 250,比勒公司)中磨平。根据陶瓷类型(Ld或Fd)、表面处理(HF+单组分粘结剂或酸蚀与底涂)以及热循环老化(TC或未老化-基线),将这些小块随机分为八组(n = 5)。在37°C蒸馏水中浸泡24小时后,将小块嵌入丙烯酸树脂中,得到由陶瓷/水门汀/复合材料组成的1-mm横截面梁。在万能材料试验机(DL-1000,巴西圣若泽杜斯坎普斯市EMIC公司;0.5 mm/min,50 kgf载荷传感器)上进行微拉伸试验。通过将破坏载荷(单位为N)除以粘结面积(单位为mm)来计算粘结强度(MPa)。在立体显微镜下检查断裂的试样,每组随机选择一个代表性样品在粘结前进行进一步分析,使用扫描电子显微镜(SEM)和能量色散X射线光谱仪(EDS)。自酸蚀处理剂对Fd(24.66±4.5)和Ld(24.73±6.9)陶瓷显示出最高的粘结强度,且表面润湿性降低。SEM和EDS显示,两种测试材料中存在具有不同形貌的相似成分。因此,自酸蚀底漆能够比HF+硅烷为树脂水门汀提供更高的粘结力。
