光活化核黄素掺杂羟基磷灰石纳米球渗入正畸粘合剂中

IF 2 3区工程技术 Q2 ANATOMY & MORPHOLOGY Microscopy Research and Technique Pub Date : 2024-09-13 DOI:10.1002/jemt.24687

Salem Almoammar, Abdullah A. Alnazeh, Muhammad Abdullah Kamran, Mohammed Mohsen Al Jearah, Muhammad Qasim, Anshad M. Abdulla

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引用次数: 0

摘要

目的：评估在正畸粘合剂中使用不同浓度的光活化核黄素掺杂羟基磷灰石（HA）纳米球（NS）（0%、1%、5% 和 10%）和单独使用 0.5 wt% RF 时，正畸托槽与珐琅质的微张力粘接强度（μTBS）、转换度（DC）、微渗漏（ML）抗菌效果和粘接残余指数（ARI）。样本按照预定的纳入标准纳入，并定位到牙釉质交界处（CEJ）。从市场上购买的羟基磷灰石纳米球（HANS）掺入了射频。在对 HANS 和 RF 掺杂的 HANS 进行表面表征评估的同时，还进行了 EDX 分析。根据正畸粘合剂改性实验对样品进行分组。第 1 组：Transbond XT 无改性；第 2 组：实验性 Transbond XT 0.5 wt% RF；第 3 组：实验性 Transbond XT 0.5 wt% RF 掺杂 1% HANS；第 4 组：实验性 Transbond XT 0.5 wt% RF 掺杂 5% HANS；第 5 组：实验性 Transbond XT 0.5 wt% RF 掺杂 10% HANS。根据不同的粘合剂改性放置支架，并对样品进行热循环。对样品进行了 μTBS、DC 和 ML 评估。使用 ARI 评估失效类型。使用四种不同浓度（0%、1%、5% 和 10%）的改性和未改性粘合剂以及仅 0.5 wt% RF 测试对变异链球菌（S.mutans）的功效。变异链球菌和 ML 的存活率是通过 Kruskal-Wallis 检验确定的。对 μTBS 的分析采用方差分析，然后进行事后 Tukey HSD 多重比较检验。第 2 组实验中，仅 Transbond XT 0.5 wt% RF 的 μTBS 最高，ML 最低。第 5 组试验性 Transbond XT 0.5 wt% RF 掺杂 10% HANS 的 μTBS 最低、ML 最高、DC 最低。在使用 Transbond XT 作为粘合剂的第 1 组样品中，突变杆状病毒和直流电的微生物数量明显最高。光活化射频掺杂的 1%和 0.5 wt%核黄素 HANS 仅用于金属托槽粘接的正畸粘合剂，可提高微拉伸粘接强度、ML、DC 和抗菌评分。第 5 组试验性 Transbond XT 0.5 wt% RF 掺杂 10% HA-NS 的样品μTBS 最低、ML 最高、DC 最低。使用 Transbond XT 作为粘合剂的第 1 组样品显示出最高的变异性嗜血杆菌微生物数量和 DC

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Photoactivated riboflavin‐doped hydroxy apatite nanospheres infiltered in orthodontic adhesives

To assess micro‐tensile bond strength (μTBS), degree of conversion (DC), microleakage (ML) antibacterial efficacy, and adhesive remnant index (ARI) of orthodontic brackets to enamel with different concentrations of photoactivated riboflavin‐doped hydroxyapatite (HA) nanospheres (NS) (0%,1%,5% and 10%) and 0.5 wt% RF alone in orthodontic adhesive. Samples were included on the predefined inclusion criteria and positioned up to the cementoenamel junction (CEJ). Hydroxy apatite nanospheres (HANS) commercially bought were doped with RF. Surface characterization of HANS and RF‐doped HANS were assessed along with EDX analysis. Samples were grouped based on experimental orthodontic adhesive modification. Group 1: Transbond XT no modification, Group 2: experimental Transbond XT 0.5 wt% RF, Group 3: experimental Transbond XT 0.5 wt% RF‐doped 1% HANS, Group 4: experimental Transbond XT 0.5 wt % RF‐doped 5% HANS and Group 5: Experimental Transbond XT 0.5 wt% RF‐doped 10% HANS. Brackets were placed based on different adhesive modifications and samples underwent thermocycling. Samples were evaluated for μTBS, DC, and ML. The type of failure was assessed using ARI. Adhesive modified and un‐modified in four different concentrations (0%, 1%, 5%, and 10%) and 0.5 wt% RF only were used to test efficacy against Streptococcus mutans (S.mutans). The survival rate of S.mutans and ML was determined using the Kruskal–Wallis Test. For the analysis of μTBS, ANOVA was employed, followed by a post‐hoc Tukey HSD multiple comparisons test. The highest μTBS and lowest ML were observed in Group 2 experimental Transbond XT 0.5 wt% RF only. The lowest μTBS, highest ML, and lowest DC was seen in Group 5 experimental Transbond XT 0.5 wt% RF‐doped 10% HANS. Samples in Group 1 in which Transbond XT was used as adhesive demonstrated significantly the highest microbial count of S.mutans and DC. Photoactivated RF‐doped HANS in 1% and 0.5 wt% Riboflavin alone in orthodontic adhesive for metallic bracket bonding improved micro tensile bond strength, ML, DC, and antibacterial scores.Research Highlights

The highest μTBS and lowest ML were observed in Group 2 experimental Transbond XT 0.5 wt% RF only.

The lowest μTBS, highest ML, and lowest DC was seen in Group 5 experimental Transbond XT 0.5 wt% RF‐doped 10% HA‐NS.

Samples in Group 1 in which Transbond XT was used as adhesive demonstrated significantly the highest microbial count of S.mutans and DC

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来源期刊

Microscopy Research and Technique 医学-解剖学与形态学

CiteScore

5.30

自引率

20.00%

发文量

233

审稿时长

4.7 months

期刊介绍： Microscopy Research and Technique (MRT) publishes articles on all aspects of advanced microscopy original architecture and methodologies with applications in the biological, clinical, chemical, and materials sciences. Original basic and applied research as well as technical papers dealing with the various subsets of microscopy are encouraged. MRT is the right form for those developing new microscopy methods or using the microscope to answer key questions in basic and applied research.