Wang Hang, Aboushelib Moustafa N, Feilzer Albert J
Department of Dental Materials Science, Academic Center for Dentistry Amsterdam (ACTA), Louwesweg 1, 1066 EA Amsterdam, The Netherlands.
Dent Mater. 2008 May;24(5):633-8. doi: 10.1016/j.dental.2007.06.030. Epub 2007 Sep 4.
Many studies in the dental literature look at the effect of different surface treatment methods on the flexure strength of zirconia where polished zirconia has been used as control. However, zirconia is subjected to different types of surface damage as a result of the CAD/CAM milling procedure and also to damage produced by other laboratory procedures in use daily.
The aim of this work was to evaluate the effect of different surface treatment methods and in particular the effect of the CAD/CAM milling procedure on the flexure strength of zirconia frameworks.
At least 20 zirconia bars (17 mmx2 mmx1 mm) for each group were prepared by either cutting and polishing zirconia milling blocks or by using a CAD/CAM device (Cercon) which left behind characteristic surface features related to the milling process. The fully sintered bars received either of the following surface treatments: air-borne particle abrasion (with 50 and 120 microm aluminum oxide particles, or both). Some bars received a heat treatment commonly used in baking veneer ceramics before or after particle abrasion. The surface roughness was measured for all bars, which were finally loaded in a three-point device. The fractured bars were examined using scanning electron microscopy. Data were analyzed using one-way analysis of variance and survivability was estimated using Weibull analysis (alpha<0.05).
There were significant differences in the flexure strength (in MPa) between the tested groups subjected to different surface treatments which can be categorized into four strength levels: (1074-1166 MPa) for polished zirconia and the CAD/CAM bars that were particle abraded (50 microm Al2O3) whether with or without heat treatment (936 MPa) for the ground bars that were particle abraded (50 microm Al2O3), (708-794 MPa) for CAD/CAM bars and for the polished bars that were particle abraded (120 microm Al2O3), and (546 MPa) for the ground bars that were particle abraded (120 microm Al2O3) being the weakest. There was a strong correlation between flexure strength and the severity of surface damage as indicated by surface roughness (R2=0.912). Scanning electron microscopy revealed different types of surface and subsurface damage produced by the different surface treatments.
The surface damage produced by the CAD/CAM milling procedure significantly reduced the strength of zirconia which could be further weakened by different surface treatment methods resulting in unexpected failures at stresses much lower than the ideal strength of the material. It is advised to consider the effect of the CAD/CAM procedure on the characteristic strength when designing zirconia-based fixed partial dentures.
牙科文献中的许多研究探讨了不同表面处理方法对氧化锆弯曲强度的影响,其中已将抛光氧化锆用作对照。然而,由于CAD/CAM铣削程序,氧化锆会受到不同类型的表面损伤,并且还会受到日常使用的其他实验室程序所产生的损伤。
本研究的目的是评估不同表面处理方法的效果,尤其是CAD/CAM铣削程序对氧化锆框架弯曲强度的影响。
每组至少制备20根氧化锆棒(17mm×2mm×1mm),方法是切割并抛光氧化锆铣削块,或使用CAD/CAM设备(Cercon),该设备会留下与铣削过程相关的特征性表面特征。完全烧结的棒材接受以下任何一种表面处理:空气颗粒研磨(使用50和120微米的氧化铝颗粒,或两者都用)。一些棒材在颗粒研磨之前或之后接受了常用于烤瓷贴面的热处理。测量所有棒材的表面粗糙度,最后将其加载到三点装置中。使用扫描电子显微镜检查断裂的棒材。使用单向方差分析对数据进行分析,并使用威布尔分析估计存活率(α<0.05)。
接受不同表面处理的测试组之间的弯曲强度(以MPa为单位)存在显著差异,可分为四个强度级别:抛光氧化锆和经颗粒研磨(50微米Al2O3)的CAD/CAM棒材,无论是否进行热处理,其弯曲强度为(1074 - 1166 MPa);经颗粒研磨(50微米Al2O3)的研磨棒材的弯曲强度为(936 MPa);CAD/CAM棒材和经颗粒研磨(120微米Al2O3)的抛光棒材的弯曲强度为(708 - 794 MPa);而经颗粒研磨(120微米Al2O3)的研磨棒材的弯曲强度最弱,为(546 MPa)。弯曲强度与表面粗糙度所表明的表面损伤严重程度之间存在很强的相关性(R2 = 0.912)。扫描电子显微镜揭示了不同表面处理产生的不同类型的表面和亚表面损伤。
CAD/CAM铣削程序产生的表面损伤显著降低了氧化锆的强度,不同的表面处理方法可能会进一步削弱其强度,从而导致在远低于材料理想强度的应力下出现意外失效情况。建议在设计基于氧化锆的固定局部义齿时考虑CAD/CAM程序对特征强度的影响。
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