Department of Dental Materials and Prosthodontics, São Paulo State University (Unesp) - Institute of Science and Technology, São José dos Campos, Brazil.
School of Dentistry, Meridional Faculty-IMED, Passo Fundo, Rio Grande do Sul State, Brazil.
J Mech Behav Biomed Mater. 2019 Jul;95:172-179. doi: 10.1016/j.jmbbm.2019.04.002. Epub 2019 Apr 9.
This study evaluated the effect of the CAD/CAM burs experience (newer vs older as consequence of the milling sequence) on fatigue failure load (FFL), number of cycles for failure (CFF), and survival rates of lithium disilicate glass-ceramic simplified restorations adhesively cemented to a dentin analogue substrate. Three sets of CAD/CAM burs were used to mill disc-shaped ceramic specimens (1 bur set - 18 milled discs with 10 mm diameter and 1.5 mm thickness), considering the bur experience as a result of the milling sequence to compose the study groups: G1-6 - discs obtained from the 1st to 6th milling of each bur set; G7-12 - specimens from the 7th to 12th milling; G13-18 - discs from the 13th to 18th. Discs of dentin analogue (G10, 10 mm diameter and 2.0 mm thickness) were made to serve as substrate (base material) and randomly assigned into pairs with the respective ceramic discs. Then, the ceramic discs were adhesively cemented onto the dentin analogue substrate, composing a three-layer specimen that mimics a monolithic restoration of a posterior tooth. Specimens were tested under stepwise fatigue approach: frequency = 20 Hz, 5000 cycles at maximum load of 400 N to accommodate the testing assembly, followed by incremental steps of 200 N with initial load ranging from 10 to 1000 N, to a maximum of 20,000 cycles/each step, until the occurrence of failure (radial crack). FFL and CFF were recorded at the end of the testing and subjected to statistical analysis. Supplementary roughness analysis of the milled surface was performed (n = 18) using a contact profilometer. Residual stress after milling and acid etching were accessed via X-ray Diffractometry analysis. FFL and CFF were not affected by increase on bur experience (no statistical differences among groups), despite that, it affected both Ra and Rz parameters (G1-6 had the smoothest surface). The residual stress concentration was negligible (milling did not induce residual stress concentration). It is concluded that the fatigue behavior of adhesively cemented lithium-disilicate glass-ceramic restorations was not influenced by CAD/CAM bur experience (newer vs older as consequence of the milling sequence), and so the residual stress concentration induced by milling was negligible.
本研究评估了 CAD/CAM 车针使用经验(新/旧车针,因铣削顺序不同)对疲劳失效负载(FFL)、失效循环次数(CFF)和玻璃陶瓷简化修复体黏结至牙本质模拟基底后的存活率的影响。三组 CAD/CAM 车针用于铣削碟形陶瓷试件(1 组车针-18 个直径为 10mm、厚度为 1.5mm 的圆片),将车针使用经验视为铣削顺序的结果,以此组成研究组:G1-6-每组车针的第 1 至 6 次铣削获得的圆片;G7-12-第 7 至 12 次铣削获得的试件;G13-18-第 13 至 18 次铣削获得的圆片。制作牙本质模拟基底(G10,直径为 10mm、厚度为 2.0mm)的圆盘作为基底(基础材料),并与相应的陶瓷圆盘随机配对。然后,将陶瓷圆片黏结到牙本质模拟基底上,组成三层试件,模拟后牙整体修复体。试件在逐步疲劳方法下进行测试:频率=20Hz,在最大负载 400N 下循环 5000 次,以适应测试组件,然后逐步增加负载 200N,初始负载范围为 10 至 1000N,每步最大 20,000 次循环/步,直至发生失效(径向裂纹)。测试结束时记录 FFL 和 CFF,并进行统计分析。使用接触式轮廓仪对铣削表面进行了补充粗糙度分析(n=18)。通过 X 射线衍射分析评估铣削和酸蚀后的残余应力。FFL 和 CFF 不受车针使用经验(各组间无统计学差异)的影响,但会影响 Ra 和 Rz 参数(G1-6 的表面最光滑)。残余应力集中可忽略不计(铣削不会引起残余应力集中)。综上所述,黏结的锂硅玻璃陶瓷修复体的疲劳性能不受 CAD/CAM 车针使用经验(新/旧车针,因铣削顺序不同)的影响,因此铣削引起的残余应力集中可忽略不计。
