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精修和抛光对用于CAD/CAM系统的二硅酸锂和硅酸锂氧化锆增强玻璃陶瓷粗糙度和光泽度的影响。

Effect of Finishing and Polishing on Roughness and Gloss of Lithium Disilicate and Lithium Silicate Zirconia Reinforced Glass Ceramic for CAD/CAM Systems.

作者信息

Vichi A, Fabian Fonzar R, Goracci C, Carrabba M, Ferrari M

出版信息

Oper Dent. 2018 Jan/Feb;43(1):90-100. doi: 10.2341/16-381-L.

DOI:10.2341/16-381-L
PMID:29284101
Abstract

OBJECTIVE

To assess the efficacy of dedicated finishing/polishing systems on roughness and gloss of VITA Suprinity and IPS e.max CAD.

METHOD

A total of 24 blocks of Suprinity and 24 of e.max were cut into a wedge shape using an InLab MC-XL milling unit. After crystallization, the 24 Suprinity wedges were divided into four subgroups: group A.1: Suprinity Polishing Set Clinical used for 30 seconds and group A.2: for 60 seconds; group A.3: VITA Akzent Plus Paste; and group A.4: spray. The 24 e.max wedges (group B) were divided into four subgroups according to the finishing procedure: group B.1: Optrafine Ceramic Polishing System for 30 seconds and group B.2: for 60 seconds; group B.3: IPS e.max CAD Crystall/Glaze paste; and group B.4: spray. After finishing/polishing, gloss was assessed with a glossmeter and roughness evaluated with a profilometer. Results were analyzed by applying a two-way analysis of variance for gloss and another for roughness (α=0.05). One specimen per each subgroup was observed with a scanning electron microscope.

RESULTS

For roughness, materials and surface were significant factors ( p<0.001). Suprinity exhibited significantly lower roughness than e.max. Also the Material-Surface Treatment interaction was statistically significant ( p=0.026). For gloss, both material and surface treatment were significant factors ( p<0.001). VITA Suprinity showed significantly higher gloss than e.max. Also the Material-Surface Treatment interaction was statistically significant ( p<0.001).

CONCLUSIONS

Manual finishing/polishing for 60 seconds and glazing paste are the most effective procedures in lowering the roughness of CAD/CAM silica-based glass ceramics. Manual finishing/polishing for 60 seconds allows milled silica-based glass ceramics to yield a higher gloss. VITA Suprinity displayed higher polishability than IPS e.max CAD.

摘要

目的

评估专用精修/抛光系统对VITA Suprinity和IPS e.max CAD的粗糙度和光泽度的影响。

方法

使用InLab MC-XL研磨设备将总共24块Suprinity和24块e.max切成楔形。结晶后,将24块Suprinity楔形分为四个亚组:A.1组:使用Suprinity临床抛光套装30秒;A.2组:使用60秒;A.3组:VITA Akzent Plus糊剂;A.4组:喷雾。24块e.max楔形(B组)根据精修程序分为四个亚组:B.1组:使用Optrafine陶瓷抛光系统30秒;B.2组:使用60秒;B.3组:IPS e.max CAD晶化/釉质糊剂;B.4组:喷雾。精修/抛光后,用光泽仪评估光泽度,用轮廓仪评估粗糙度。采用双向方差分析对光泽度和粗糙度的结果进行分析(α = 0.05)。每个亚组取一个样本用扫描电子显微镜观察。

结果

对于粗糙度,材料和表面是显著因素(p < 0.001)。Suprinity的粗糙度显著低于e.max。材料-表面处理交互作用也具有统计学意义(p = 0.026)。对于光泽度,材料和表面处理都是显著因素(p < 0.001)。VITA Suprinity的光泽度显著高于e.max。材料-表面处理交互作用也具有统计学意义(p < 0.001)。

结论

手动精修/抛光60秒和釉质糊剂是降低CAD/CAM硅基玻璃陶瓷粗糙度的最有效方法。手动精修/抛光60秒可使研磨后的硅基玻璃陶瓷产生更高的光泽度。VITA Suprinity比IPS e.max CAD表现出更高的可抛光性。

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