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碳酸氢钠空气喷砂抛光对陶瓷和不锈钢托槽磨损和表面微观形貌的影响。

Effect of sodium bicarbonate air abrasive polishing on attrition and surface micromorphology of ceramic and stainless steel brackets.

机构信息

Department of Orthodontics, Dental School and Institute and Research Center São Leopoldo Mandic, São Paulo, Brazil.

出版信息

Angle Orthod. 2012 Mar;82(2):351-62. doi: 10.2319/040111-235.1. Epub 2011 Aug 9.

DOI:10.2319/040111-235.1
PMID:21827231
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8867940/
Abstract

OBJECTIVES

To evaluate the frictional resistance of ceramic and metal brackets using rectangular stainless steel orthodontic wires before and after using sodium bicarbonate air abrasive polishing and to evaluate the surface micromorphology of these brackets by means of scanning electron microscopy.

MATERIALS AND METHODS

Two commercial brands of metal brackets and two commercial brands of ceramic brackets were evaluated. The specimens were divided into eight groups (n  =  10) according to brackets and the application or not of sodium bicarbonate airborne particle abrasion for 10 seconds. A device adapted to a universal testing machine was used to simulate the movement of retraction in sliding mechanics, measuring the traction force needed to slide 10 mm of the wire over the test specimen brackets. The test speed was 5 mm/min. The data were analyzed by two-way analysis of variance (ANOVA) and Tukey test.

RESULTS

There was higher frictional resistance after airborne particle abrasion irrespective of the type of bracket (P < .05). One of the ceramic brackets showed higher frictional resistance before and after airborne application than the other metal and ceramic brackets. The micromorphologic analysis showed that airborne particle abrasion caused alterations on the metal bracket surfaces.

CONCLUSIONS

It may be concluded that it is not recommended to apply airborne particle abrasion on the slots of ceramic or metal brackets.

摘要

目的

评估使用碳酸氢钠空气喷砂抛光前后陶瓷和金属托槽与矩形不锈钢正畸丝之间的摩擦阻力,并通过扫描电子显微镜评估这些托槽的表面微观形貌。

材料和方法

评估了两种商业品牌的金属托槽和两种商业品牌的陶瓷托槽。根据托槽以及是否应用碳酸氢钠空气颗粒喷砂 10 秒,将标本分为 8 组(n  =  10)。使用适配于万能试验机的装置模拟滑动力学中的回缩运动,测量将 10 毫米的金属丝在测试标本托槽上滑动 10 毫米所需的牵引力。测试速度为 5 毫米/分钟。采用双向方差分析(ANOVA)和 Tukey 检验对数据进行分析。

结果

无论托槽类型如何,经空气颗粒喷砂后摩擦阻力均升高(P <.05)。一种陶瓷托槽在空气颗粒喷砂前后的摩擦阻力均高于其他金属和陶瓷托槽。微观形貌分析显示,空气颗粒喷砂导致金属托槽表面发生改变。

结论

综上所述,不建议在陶瓷或金属托槽的槽沟上应用空气颗粒喷砂。

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