목적: 레진 시멘트와 코발트크롬 합금 간의 미세인장결합강도에 다양한 프라이머들이 미치는 영향을 평가하기 위한 것이다. 재료 및 방법: 본 실험에서는 4개의 프라이머(Universal primer, Metal primer II, Alloy primer, and Metal/Zirconia primer)와 2개의 레진 시멘트(Panavia F2.0, G-CEM LinkAce)를 사용하였고, 길이 6 mm, 폭 1 mm, 두께 1 mm의 150개의 코발트 크롬 빔들이 캐스팅 과정을 통해 제작되었다. 150개의 코발트 크롬 빔들을 프라이머와 레진 시멘트의 종류에 따라 프라이머 처리를 하지 않은 대조군을 포함하여 10개 그룹으로 나누었다. 금속과 레진시멘트를 산화알루미늄($125{\mu}m$ 크기)으로 샌드블라스팅 처리한 후 실리콘 틀을 이용하여 접착시켰다. 실험 전에, 입체현미경(stereomicroscope)을 이용하여 모든 금속-레진 빔들을 검사하였고, 미세인장결합강도 실험을 시행하였다. 통계적인 평가에는 one-way ANOVA와 Tukey's test를 사용하였다. 결과: 모든 그룹들의 평균 미세인장결합강도는 20 - 28 MPa이었으며, 그룹 간에 통계적으로 유의한 차이는 없었다. Panavia F2.0과 G-CEM LinkAce 그룹 모두에서 접착 파절과 응집 파절이 동시에 나타나는 혼합 파절이 가장 흔하게 일어난 파절 양태였다. 결론: 모든 실험군들의 미세인장결합강도는 상대적으로 높았지만, 본 실험에서는 프라이머의 사용이 Panavia F2.0 및 G-CEM LinkAce 레진시멘트와 코발트 크롬 합금 사이의 미세인장결합강도를 증가시키지 않았다.
목적: 레진 시멘트와 코발트 크롬 합금 간의 미세인장결합강도에 다양한 프라이머들이 미치는 영향을 평가하기 위한 것이다. 재료 및 방법: 본 실험에서는 4개의 프라이머(Universal primer, Metal primer II, Alloy primer, and Metal/Zirconia primer)와 2개의 레진 시멘트(Panavia F2.0, G-CEM LinkAce)를 사용하였고, 길이 6 mm, 폭 1 mm, 두께 1 mm의 150개의 코발트 크롬 빔들이 캐스팅 과정을 통해 제작되었다. 150개의 코발트 크롬 빔들을 프라이머와 레진 시멘트의 종류에 따라 프라이머 처리를 하지 않은 대조군을 포함하여 10개 그룹으로 나누었다. 금속과 레진시멘트를 산화알루미늄($125{\mu}m$ 크기)으로 샌드블라스팅 처리한 후 실리콘 틀을 이용하여 접착시켰다. 실험 전에, 입체현미경(stereomicroscope)을 이용하여 모든 금속-레진 빔들을 검사하였고, 미세인장결합강도 실험을 시행하였다. 통계적인 평가에는 one-way ANOVA와 Tukey's test를 사용하였다. 결과: 모든 그룹들의 평균 미세인장결합강도는 20 - 28 MPa이었으며, 그룹 간에 통계적으로 유의한 차이는 없었다. Panavia F2.0과 G-CEM LinkAce 그룹 모두에서 접착 파절과 응집 파절이 동시에 나타나는 혼합 파절이 가장 흔하게 일어난 파절 양태였다. 결론: 모든 실험군들의 미세인장결합강도는 상대적으로 높았지만, 본 실험에서는 프라이머의 사용이 Panavia F2.0 및 G-CEM LinkAce 레진시멘트와 코발트 크롬 합금 사이의 미세인장결합강도를 증가시키지 않았다.
Purpose: The aim of this study is to evaluate the effects of various primers on the microtensile bond strength (${\mu}TBS$) of resin cements to cobalt-chromium (Co-Cr) dental casting alloy. Materials and methods: Four adhesive primers (Universal primer, Metal primer II, Alloy primer, and ...
Purpose: The aim of this study is to evaluate the effects of various primers on the microtensile bond strength (${\mu}TBS$) of resin cements to cobalt-chromium (Co-Cr) dental casting alloy. Materials and methods: Four adhesive primers (Universal primer, Metal primer II, Alloy primer, and Metal/Zirconia primer) and two resin cements (Panavia F2.0, G-CEM LinkAce) were tested. One hundred fifty Co-Cr beams were prepared from Co-Cr ingots via casting ($6mm\;ength{\times}1mm\;width{\times}1mm\;thick$). The metal beams were randomly divided into ten groups according to the adhesive primers and resin cements used; the no-primer groups served as the control (n = 15). After sandblasting with aluminum oxide ($125{\mu}m$ grain), the metal and resin cements were bonded together using a silicone mold. Prior to testing, all metal-resin beams were examined under stereomicroscope, and subjected to the ${\mu}TBS$ test. The mean value of each group was analyzed via one-way ANOVA with Tukey's test as post hoc (${\alpha}=.05$) using SPSS software. Results: The mean ${\mu}TBS$ of all groups was ranged from 20 to 28 MPa. There is no statistically significant difference between groups (P > .05). Mixed failure, which is the combination of adhesive and cohesive failures, is the most prevalent failure mode in both the Panavia F2.0 and G-Cem LinkAce groups. Conclusion: The ${\mu}TBS$ of all tested groups are relatively high; however, the primers used in this study result in no favorable effect in the ${\mu}TBS$ of Panavia F2.0 and G-Cem LinkAce resin cement to Co-Cr alloy.
Purpose: The aim of this study is to evaluate the effects of various primers on the microtensile bond strength (${\mu}TBS$) of resin cements to cobalt-chromium (Co-Cr) dental casting alloy. Materials and methods: Four adhesive primers (Universal primer, Metal primer II, Alloy primer, and Metal/Zirconia primer) and two resin cements (Panavia F2.0, G-CEM LinkAce) were tested. One hundred fifty Co-Cr beams were prepared from Co-Cr ingots via casting ($6mm\;ength{\times}1mm\;width{\times}1mm\;thick$). The metal beams were randomly divided into ten groups according to the adhesive primers and resin cements used; the no-primer groups served as the control (n = 15). After sandblasting with aluminum oxide ($125{\mu}m$ grain), the metal and resin cements were bonded together using a silicone mold. Prior to testing, all metal-resin beams were examined under stereomicroscope, and subjected to the ${\mu}TBS$ test. The mean value of each group was analyzed via one-way ANOVA with Tukey's test as post hoc (${\alpha}=.05$) using SPSS software. Results: The mean ${\mu}TBS$ of all groups was ranged from 20 to 28 MPa. There is no statistically significant difference between groups (P > .05). Mixed failure, which is the combination of adhesive and cohesive failures, is the most prevalent failure mode in both the Panavia F2.0 and G-Cem LinkAce groups. Conclusion: The ${\mu}TBS$ of all tested groups are relatively high; however, the primers used in this study result in no favorable effect in the ${\mu}TBS$ of Panavia F2.0 and G-Cem LinkAce resin cement to Co-Cr alloy.
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문제 정의
The purpose of this study is to evaluate the effects of various primers on the microtensile bond strength of resin cements to a Co-Cr dental casting alloy.
제안 방법
In this study, we evaluate two adhesive systems: a conventional resin cement, Panavia F2.0, and a self-adhesive resin cement, G-Cem LinkAce. The 10-MDP, contained in Panavia F2.
Other factors that may influence the durability of resin bonding and that were not evaluated in this study include pH changes, dynamic fatigue loading, thermocycling, and the various components of the resin cement and primer. Therefore, careful interpretation in the clinical application of these results is suggested and further in vitro research and standardized studies must be conducted to confirm the efficacy of the tested systems.
대상 데이터
In this study, we used Co-Cr alloy, four adhesive primers and two resin cements. Specific information concerning the materials utilized in this study is presented in Table 1.
Specific information concerning the materials utilized in this study is presented in Table 1. One hundred fifty Co-Cr metal beams (6 mm long, 1 mm wide, and 1 mm thick) were casted. After trimming and polishing the beams, the bonding surfaces were sandblasted with aluminum oxide (125 µm grain) for 5 seconds at 80-psi pressure.
데이터처리
The mean of each group was analyzed via one-way ANOVA with microtensile bond strength (µTBS) as the dependent variable, primer treatment as the independent factor, and Tukey’s test as post hoc (α = .05) using SPSS software (SPSS ver. 22.0, IBM, Chicago, IL, USA).
후속연구
Other factors that may influence the durability of resin bonding and that were not evaluated in this study include pH changes, dynamic fatigue loading, thermocycling, and the various components of the resin cement and primer. Therefore, careful interpretation in the clinical application of these results is suggested and further in vitro research and standardized studies must be conducted to confirm the efficacy of the tested systems.
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