Evaluation of enamel surface integrity after orthodontic bracket debonding: comparison of three different system

Dental enamel, the most mineralized tissue in the human body, forms the external protective layer of a tooth’s anatomical crown [1]. Fixed orthodontic brackets are temporary appliances attached to the teeth for a certain period, depending on the severity of the malocclusion, and need to be removed at the end of treatment [2]. Significant efforts are made to minimize the risk of enamel surface damage and restore the enamel surface promptly after orthodontic debonding and resin removal [3]. If the roughened areas are left untreated, they may promote dental plaque accumulation, subsequent enamel demineralization, and decay. Another concern is the discoloration of composite remnants over time, causing an unaesthetic appearance [4]. Therefore, the primary goal of bracket debonding is to remove orthodontic debonding and adhesive remnants from tooth surfaces without causing iatrogenic damage.

Many methods were used for bracket debonding, such as manual, rotary instruments, ultrasonic, air abrasion by sandblast, and lasers [5‐7]. Different factors, including the bur type, its rotational speed, the number of blades, and the material composition, influence the extent of the enamel damage during adhesive removal [8, 9]. Tungsten Carbide system (TC) is perfect for cutting ductile materials such as composite resins. The rotation of these burs generates high shear forces between the bur’s blades and the resin surface, resulting in the plastic plowing of the resin. Many TC are available on the market, and almost all of them have been recommended for adhesive removal in the literature [10]. Employ the SD system, ranging from coarse to extra fine, to attain a smooth enamel surface. These discs can be used alone or in conjunction with TC system. While it is feasible to use Sof-lex discs independently for adhesive removal and enamel polishing, this method is more time-consuming than when combined with burs. Nonetheless, SD system is effective in easily flattening the enamel surface [11].

Dental loupes are extensively employed in dentistry due to their significant benefits in enhancing ergonomics. This widely adopted tool not only aids in magnification but also contributes to better posture and reduced strain for dental professionals during procedures [12, 13]. Orthodontic treatments require a clear view of one or both dental arches, and using magnifying loupes might help with certain tasks like placing brackets or removing adhesive after debonding by giving better visual control [14]. Based on our knowledge, no technique has been shown to thoroughly and efficiently remove residual adhesives without causing at least some minor damage to the enamel. The null hypothesis is that there are no differences in the integrity of the enamel surface after orthodontic deboning adhesive removal after using three different burs with and without the aid of a dental loupe. It also suggests no significant difference in the time taken for adhesive removal. Therefore, this study worked to prove or reject this null hypothesis.

The study protocol was approved by the ethical and research committee at China Medical University, School of Stomatology, and has been conducted in full accordance with the Declaration of Helsinki. The sample size was calculated using G* Power software (v3.1.3; Franz Faul, Universität Kiel, Germany) which depends on the effect size = 0.80, an alpha value of 0.05, and a power of 95%. The result showed that at least 15 samples were required in each group based on the study conducted by Thawaba et al. [15]. However, the sample size was raised to 20 samples for each study group.

The statistical examination of ARI after bracket debonding demonstrates no statistically significant distinctions among the groups, allowing for comparison of all groups for resin removal and enamel polishing. Furthermore, there is no significant difference in the average roughness values among all subgroups at T0 (p = 0.994), making all groups comparable (Supplemental Table 1).

The Kruskal–Wallis test demonstrated a statistically significant difference in roughness values between all studied subgroups at both T1 and T2 (p < 0.001). After removing residual cement T1, Tukey HSD tests indicated a statistically significant difference between all subgroup pairs, except for NTC-NSD, NTC-MSD, and NSD-MSD, with a p-value > 0.05. At polishing stage T2, the Tukey HSD tests showed a statistically significant difference between the NDB subgroup and all other subgroups, as well as between the MDB subgroup and all other subgroups, with a p < 0.05 (Table 2,3).

There was a significant difference in the average roughness values between T0, T1, and T2 in all subgroups (p < 0.001, Fig. 2). When comparing the surface roughness, it was found that there was a statistically significant difference in mean roughness values at T1 vs. both T0 and T2 in NDB and MDB (p < 0.05.) (Table 4).

When comparing the EDI at T1 and T2, the Kruskal–Wallis H-test showed statistically significant differences in all subgroups. The pairwise comparisons revealed that EDI scores showed a statistically significant difference at T1 and T2 between DB vs. TC and SD (p = 0.015) but not between TC vs. SD (p = 1.000, Table 5).

Under SEM, the enamel surface before bonding showed a smooth surface without scratches or grooves (Fig. 3). After adhesive resin removal, the TC and SD groups showed an EDI score 2 in the naked eye group. The EDI score in the magnifying loupe group was 1 in the TC group, and score 2 in SD group. While the DB group showed an EDI score 3 in both the naked eye and magnifying loupe groups (Fig. 4). The sequential polishing using the Silicone One-Gloss produced a smoother and more homogeneous enamel surface in samples treated with TC and SD burs. However, after polishing, the samples treated by DB burs still had a slightly permanent roughened surface with fewer scratches and shallow grooves (Fig. 5).

A one-way ANOVA test was applied to compare the time consumed for adhesive resin removal for all groups, revealing a statistically significant difference in all subgroups (p < 0.001); the TC group took the least amount of working time to remove residual cement (p = 0.000). Furthermore, the duration taken for adhesive resin removal was significantly reduced in the magnifying loupe groups compared to the naked eye groups (p = 0.001), as shown in Fig. 6.

In orthodontics, the techniques used for attaching and removing orthodontic brackets are critical. Numerous factors impact these procedures, including the choice of adhesive, the bracket debonding instruments, and the methods employed for finishing and polishing to remove adhesive resin [20].

Advances composite resin and adhesive systems have improved the bond between enamel and resin. Nonetheless, this stronger adhesion complicates the removal of residual resin following debonding. The method for removing residual resin is crucial to avoid damage to the enamel surface. Potential damages include cracking, roughness, wear, overheating of the teeth, damage to the pulp, and altered tooth color. Proper removal techniques are vital to maintaining a good aesthetic appearance and surface brightness [21‐27]. No technique has been proven to thoroughly and efficiently remove residual adhesives without causing at least minor damage to the enamel [21]. The ideal finishing procedure after debonding should minimize enamel tissue removal and smooth the surface [23]. However, no standard protocol, systematic review, or meta-analysis is available to guide dental practitioners in their daily work routine. Some practitioners use the DB system to reduce chair time, but even with experience and careful use of rotary instruments, enamel crystals can be damaged during mechanical removal.

This study examined the effects of various adhesive removal systems (TC, SD, and DB) on enamel surface roughness after de-bracketing, with and without using a magnifying loupe. Profilometric analysis and SEM were employed to compare the outcomes and measure the time required for adhesive removal. Our findings indicated that the TC group at T1 produced the least enamel surface roughness, followed by the SD group, while the DB group resulted in the highest surface roughness. SEM analysis corroborated these findings, showing an EDI score 2 for TC system and a score 3 for DB in both the naked eye and magnifying loupe groups. These results were consistent with a study conducted by Janiszewska-Olszowska et al.[21] and Sugsompian et al.[24] who found TC system to be more effective in adhesive removal with minimal surface roughness compared to white stones, advising against using white stones due to severe irreversible enamel damage. On the other hand, these findings disagreed with the findings of Mohebi et al.[25] who reported no significant differences in surface roughness between white stones and TC system, possibly due to their use of white stone burs on low-speed handpieces.

Many studies have used different types of burs for polishing procedures. In our experiment, we used Silicone OneGloss bur, which was not found in any previous research that used this bur. Our research findings indicated that the enamel surface in both the TC and SD groups was nearly returned to its pre-treatment condition following the polishing. The results gave a smooth surface and less time than other burs like SD spiral, which needs to change the spiral and consumes time [26‐28]. However, the surface roughness decreased significantly in the DB group, but the surface still had a slightly rough surface with shallow grooves. These findings were confirmed by SEM analysis, where the NTC, MTC, and MSD subgroups scored 1 on EDI, while the MDB and NDB subgroups scored 3 on EDI. This finding was in line with studies conducted by Degrazia et al.[29], Janiszewska-Olszowska et al.[21] and Schiefelbein and Rowland [30]. On the other hand, Howell and Weekes[31] disagreed with these results, concluding that medium and fine SD produced a rough surface during polishing. A potential explanation for this discrepancy might be that the SD system was used in a dry condition.

To minimize the risk of enamel damage, we used a low-speed handpiece for adhesive resin removal, which may take longer compared to using a high-speed handpiece [3, 32] The time required to remove adhesive resin with various systems was significantly shorter in the magnifying loupe group than in the naked eye group. The TC system proved to be the least time-consuming for the whole duration of the residual cement removal procedure, followed by SD system. In contrast, the duration of the removal procedure of the remaining cement was the longest with the diamond system. Similar to our results, Tenório et al.[33] Shafiee et al.[34], and Ulusoy [23] showed that the time spent for resin removal with the TC bur was shorter than polymer bur and white stones, respectively. On the other hand, Thawaba et al. [15] reported that. Zirconia burs were more effective for adhesive resin removal than TC systems, causing the least surface roughness and enamel damage.

Regardless of the system chosen for resin removal and finishing, using a magnifying loupe effectively aided in removing adhesive resin with less surface roughness and enamel damage, and it also decreased the time required to remove the adhesive resin. This outcome is in consistent with Baumann et al. [14]. On the other hand, Mohebi et al. [25] found no statistically significant differences in enamel surface roughness and time consumption between the naked eye and loupe magnification groups.

Some limitations of this study have to be mentioned. Firstly, it was carried out in vitro, which does not entirely simulate the conditions inside the mouth. Secondly, we did not evaluate the biological impact of the methods tested on the pulp or dentine. Future studies might benefit from using atomic force microscopy and confocal laser microscopy for a three-dimensional assessment of enamel surface roughness. Lastly, to substantiate our findings and their applicability in clinical practice, further in vivo studies are needed.

All three burs were clinically effective for removing residual orthodontic adhesive. TC system represents the best one to remove the adhesive resin with a short time consumption comparable to SD burs and can be considered an alternative to DB, which causes severe enamel damage. Regardless of the type of bur used for resin removal, the polishing step by Silicone OneGloss created a smoother surface for the naked eye and was better with a magnifying loupe.