Comparison of Microleakage Under Orthodontic Brackets Bonded with Five Different Adhesive Systems: in Vitro Study

Overview

Journal BMC Oral Health

Publisher Biomed Central

Specialty Dentistry

Date 2023 Sep 5

PMID 37670283

Authors

Nela Masarykova

Emil Tkadlec

Zdenek Chlup

Jan Vrbsky

Alena Brysova

Pavlina Cernochova

Lydie Izakovicova Holla

Affiliations

Soon will be listed here.

Abstract

Background: Orthodontic treatment is associated with numerous adverse side effects, such as enamel discoloration, demineralization or even caries. The presence of microleakage between the enamel and the adhesive and between the adhesive and the base of the orthodontic bracket allows penetration of the bacteria, molecules, and liquids into the enamel and can lead to unpleasant "white spot lesions" or secondary caries beneath and around the brackets. The aim of this in vitro study was to evaluate microleakage in five adhesive systems commonly used in orthodontic practice for bonding brackets.

Methods: One hundred extracted premolars were divided into five groups of twenty teeth. Stainless steel Legend medium metal brackets were bonded to teeth using five adhesive systems: resin-reinforced glass ionomer cement GC Fuji Ortho LC (GCF) and composite materials Light Bond (LB), Transbond XT (TB), Trulock™ Light Activated Adhesive (TL), and GC Ortho Connect (GCO). The specimens were subjected to thermal cycling, stained with 2% methylene blue, sectioned with low-speed diamond saw Isomet and evaluated under a digital microscope. Microleakage was detected at the enamel-adhesive and adhesive-bracket interfaces from occlusal and gingival margins. Statistical analysis was performed using generalized linear mixed models with beta error distribution.

Results: Microleakage was observed in all materials, with GCF showing the highest amount of microleakage. Composite materials GCO, TB, and LB exhibited the lowest amount of microleakage with no statistical difference between them, while TL showed a statistically significantly higher amount of microleakage (p < 0.001). The enamel-adhesive interface had more microleakage in all composite materials (GCO, LB, TB, and TL) than the adhesive bracket-interface (p < 0.001). The highest amount of microleakage occurred in the gingival region in all materials.

Conclusion: Composite materials showed better adhesive properties than a resin-reinforced glass ionomer cement. The presence of microleakage at the enamel-adhesive interface facilitates the penetration of various substances into enamel surfaces, causing enamel demineralization and the development of dental caries.

Citing Articles

Evaluation of Microleakage in Flash-Free and Conventional Ceramic Brackets: A Microcomputed Tomography Study.

Ustdal G, Kucuk E Turk J Orthod. 2025; 37(4):242-248.

PMID: 39743863 PMC: 11705194. DOI: 10.4274/TurkJOrthod.2024.2024.21.

Comparison of Microleakage and Bond Strength in Metal and Ceramic Brackets Cured by Conventional and Transillumination Methods: An Evaluation.

Lenin A, Anbarasu P, Kumar S, Narayanan A, Dhingra R, Ramesh B Int J Clin Pediatr Dent. 2024; 17(9):999-1003.

PMID: 39664832 PMC: 11628689. DOI: 10.5005/jp-journals-10005-2921.

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