Evaluation of antibacterial properties and shear bond strength of orthodontic composites containing silver nanoparticles, titanium dioxide nanoparticles and fluoride: An in vitro study

MAHENDRA, Tivanani Venkata Durga; MUDDADA, Vizia; GORANTLA, Suresh; KARRI, Tarakesh; MULAKALA, Vyshnavi; PRASAD, Ratnavati; CHINTALA, Sarath Kumar; MOUNICA, Kotta

doi:10.1590/2177-6709.27.5.e222067.oar

ABSTRACT

Objective:

The study aimed at determining the antibacterial properties of composites containing silver nanoparticles (Ag NPs) or titanium dioxide nanoparticles (TiO₂ NPs), and a fluoride-releasing composite against Streptococcus mutans and Lactobacillus acidophilus, and to evaluate the effect on shear bond strength (SBS) of nanoparticles-modified composites.

Materials and Methods:

An orthodontic composite was modified by adding 1% w/w Ag NPs or 1% w/w TiO₂ NPs. Composite discs were prepared to evaluate the antibacterial properties of these modified composites against Streptococcus mutans and Lactobacillus acidophilus, using three different antibacterial tests, namely: Disk agar diffusion test, Biofilm inhibition test and eluted component test. For evaluating the shear bond strength, 80 extracted premolars were collected and divided into four groups (n=20 each), which were bonded with stainless steel preadjusted Edgewise brackets, by using these modified composites. Their SBS was then compared with that of the control group, using a universal testing machine.

Results:

Composite discs containing nanoparticles and fluoride were capable of producing growth inhibition zones for all bacterial types. Results of the biofilm inhibition test showed that all the study groups inhibited the bacterial count, in comparison to the control group. A significant difference of SBS was observed between all groups.

Conclusion:

The antibacterial activity of orthodontic composites modified with Ag and TiO₂ nanoparticles was significant, compared with conventional and fluoride-containing composites. The control group showed the highest SBS, followed by fluoride, titanium, and silver groups, with statistically significant difference in mean SBS values among all groups.

Keywords:
Metal nanoparticles; Nanocomposite; Antibacterial activity; Shear strength

RESUMO

Objetivo:

O objetivo do presente estudo foi determinar a eficácia das propriedades antibacterianas de compósitos contendo nanopartículas de prata (Ag NPs) ou nanopartículas de dióxido de titânio (TiO₂ NPs) e de um compósito com liberação de flúor, contra as bactérias Streptococcus mutans e Lactobacillus acidophilus e, também, avaliar o efeito na resistência ao cisalhamento (RC) desses compósitos modificados com nanopartículas.

Métodos:

Os compósitos ortodônticos foram modificados pela adição de 1% p/p de Ag NPs e 1% p/p de TiO₂ NPs. Discos de compósito foram preparados para avaliar as propriedades antibacterianas desses grupos contra as bactérias Streptococcus mutans e Lactobacillus acidophilus, usando três testes antibacterianos diferentes: teste de disco-difusão em ágar, teste de inibição da formação de biofilme e teste de componentes eluídos. Para avaliar a resistência ao cisalhamento dos compósitos, 80 pré-molares extraídos foram coletados e divididos em quatro grupos, contendo 20 dentes cada. Foram utilizados braquetes Edgewise pré-ajustados de aço inoxidável para colagem nos dentes usando as resinas modificadas. A RC desses compósitos modificados foi comparada à dos grupos controle, usando uma máquina universal de testes.

Resultados:

Os discos de compósito contendo as nanopartículas e flúor foram capazes de produzir halos de inibição de crescimento para todos os tipos de bactérias. Os resultados do teste de inibição do biofilme mostraram que houve uma redução na contagem de bactérias em relação ao grupo controle. Diferenças significativas na RC foram observadas entre todos os grupos.

Conclusão:

A atividade antibacteriana dos compósitos ortodônticos modificados com nanopartículas de Ag e TiO₂ foi significativa, quando comparada ao compósito convencional e ao compósito com flúor. O grupo controle apresentou a maior RC, seguido pelos grupos Flúor, Titânio e Prata, com diferença estatisticamente significativa nos valores médios da RC entre todos os grupos.

Palavras-chave:
Nanopartículas metálicas; Nanocompósito; Atividade antimicrobiana; Força de cisalhamento

INTRODUCTION

Demineralization of the enamel surface during fixed orthodontic treatment was a common complication encountered in orthodontic patients.¹1 Altmann AS, Collares FM, Leitune VC, Samuel SM. The effect of antimicrobial agents on bond strength of orthodontic adhesives: a meta-analysis of in vitro studies. Orthod Craniofac Res. 2016;19(1):1-9. Brackets and fixed orthodontic attachments facilitate plaque accumulation by providing retentive areas.²2 Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7.Streptococcus mutans and Lactobacillus causes a rapid shift in the microflora of plaque, resulting in elevated levels of acidogenic environment.³3 Manfred L, Covell DA, Crowe JJ, Tufekci E, Mitchell JC. A novel biomimetic orthodontic bonding agent helps prevent white spot lesions adjacent to brackets. Angle Orthod. 2013;83(1):97-103. The acidic byproducts of these bacteria in plaque are responsible for the subsequent enamel demineralization and formation of white spot lesions.⁴4 Papaioannou W, Gizani S, Nassika M, Kontou E, Nakou M. Adhesion of Streptococcus mutans to different types of brackets. Angle Orthod. 2007;77(6):1090-5.

The use of specific nanoparticles (NPs) as antibacterial agents has attracted much attention recently, in the fields of medicine and dentistry.⁵5 Al-Eesa NA, Wong FS, Johal A, Hill RG. Fluoride containing bioactive glass composite for orthodontic adhesives-ion release properties. Dent Mater. 2017;33(11):1324-9. The physicochemical nature of these NPs enables them to interact with the negatively charged surface of bacterial cells to a greater extent, resulting in enhanced antibacterial activity.⁶6 Govindankutty D. Applications of nanotechnology in orthodontics and its future implications: a review. Int J Appl Dent Sci. 2015;1(4):166-71.Streptococcus mutans are known to be sensitive to nanoparticles of silver, zinc oxide, gold and titanium, and significant clinical effects can be observed with the use of these nanoparticles.⁷7 Hernández-Sierra JF, Ruiz F, Pena DC, Martínez-Gutiérrez F, Martínez AE, Guillén AD, et al. The antimicrobial sensitivity of Streptococcus mutans to nanoparticles of silver, zinc oxide, and gold. Nanomedicine2008;4(3):237-40.

Ag NPs have distinctive characteristics that make them a possible choice to be used as fillers for dental composites.⁸8 Al-Nafori MK, Elshal MG, Refai WM. The effect of incorporating gold and silver nanoparticles in orthodontic adhesive system on bond strength of orthodontic bracket. EC Dent Sci. 2017;11(4):119-131. TiO₂ plays a vital role in organic degradation processes, due to its properties, such as biocompatibility and chemical stability.⁹9 Salehi P, Babanouri N, Roein-Peikar M, Zare F. Long-term antimicrobial assessment of orthodontic brackets coated with nitrogen-doped titanium dioxide against Streptococcus mutans. Prog Orthod. 2018;19(1):35. TiO₂ NPs, when investigated, exhibited superior antibacterial activity against Streptococcus mutans.¹⁰10 Elsaka SE, Hamouda IM, Swain MV. Titanium dioxide nanoparticles addition to a conventional glass-ionomer restorative: influence on physical and antibacterial properties. J Dent. 2011;39(9):589-98.

The concentration and distribution of nanofiller particles into the orthodontic adhesives are critical parameters that affect the antibacterial properties and their shear bond strength (SBS). Previous studies¹¹11 Sodagar A, Akhavan A, Hashemi E, Arab S, Pourhajibagher M, Sodagar K, et al. Evaluation of the antibacterial activity of a conventional orthodontic composite containing silver/hydroxyapatite nanoparticles. Prog Orthod. 2016;17(1):40.

12 Naslapur S, Malik SA, Laxmikanth SM, Ramachandra CS. The effect of silver oxide nanoparticles on the antibacterial property and shear bond strength of dental composite. Dent Health Curr Res. 2019;5(1).^-¹³13 Akhavan A, Sodagar A, Mojtahedzadeh F, Sodagar K. Investigating the effect of incorporating nanosilver/nanohydroxyapatite particles on the shear bond strength of orthodontic adhesives. Acta Odontol Scand. 2013;71(5):1038-42. have shown that the addition of 1%, 5% or 10% w/w concentrations of silver/hydroxyapatite NPs to the orthodontic adhesives increased the antibacterial properties, but simultaneously affected the SBS. The incorporation of 1% and 5% w/w of these NPs maintained the SBS of orthodontic adhesives, whereas increasing its concentration up to 10% w/w significantly decreased the SBS of orthodontic adhesives.¹¹11 Sodagar A, Akhavan A, Hashemi E, Arab S, Pourhajibagher M, Sodagar K, et al. Evaluation of the antibacterial activity of a conventional orthodontic composite containing silver/hydroxyapatite nanoparticles. Prog Orthod. 2016;17(1):40.

12 Naslapur S, Malik SA, Laxmikanth SM, Ramachandra CS. The effect of silver oxide nanoparticles on the antibacterial property and shear bond strength of dental composite. Dent Health Curr Res. 2019;5(1).^-¹³13 Akhavan A, Sodagar A, Mojtahedzadeh F, Sodagar K. Investigating the effect of incorporating nanosilver/nanohydroxyapatite particles on the shear bond strength of orthodontic adhesives. Acta Odontol Scand. 2013;71(5):1038-42.

Thus, the present study aimed at incorporating 1% (w/w) TiO₂ NPs and 1% (w/w) Ag NPs into a commonly used orthodontic adhesive, evaluating the antibacterial properties and the SBS of the modified composites, and comparing it with a fluoride-releasing composite and a conventional composite.

MATERIAL AND METHODS

Nanoparticles used for the study

» TiO₂ NPs (dry nanopowder, anatase phase, average primary particle size: 30-50 nm; purity: > 99.5%, Nano Research Lab, Jamshedpur, Jharkhand, India).
» Ag NPs (dry nanopowder, average primary particle size: 30 - 50 nm; purity: > 99.5%, Nano Research Lab, Jamshedpur, Jharkhand, India).

Adhesives used for the study

» Conventional orthodontic composite (Enlight, Ormco Corp, CA).
» Fluoride-releasing composite (Light Bond, Reliance Ortho Products, Illinois, USA).

Media used for bacterial culture

» Mueller-Hinton agar (MHA) media (Hi-Media Laboratories Pvt. Ltd, Visakhapatnam, Andhra Pradesh, India).
» Brain-Heart Infusion broth (BHI broth) (Hi-Media Laboratories Pvt. Ltd, Visakhapatnam, Andhra Pradesh, India).

Types of bacterial strains used

»Streptococcus mutans (MTCC 497), CSIR - Institute of Microbial Technology, Chandigarh, Punjab, India.
»Lactobacillus acidophilus (MTCC 10307), CSIR - Institute of Microbial Technology, Chandigarh, Punjab, India.

Equipment used

» Composite mixer - High Energy Ball Mill (Retsch-Emax, Centre for Nanotechnology & Centre for Excellence, Andhra University, Visakhapatnam, Andhra Pradesh, India).
» Scanning Electron Microscope (JEOL JSM-881 OSV, Advanced Analytical Laboratory DST, Andhra University, Visakhapatnam, Andhra Pradesh, India).
» Universal testing machine: Instron (model-8801, Norwood, MA, USA).

Methodology

This study consisted of 1 control group and 3 experimental groups:

» Group I: control group - conventional composite.
» Group II: titanium group - composite containing 1% w/w TiO₂ NPs.
» Group III: silver group - composite containing 1% w/w Ag NPs.
» Group IV: fluoride group - fluoride-releasing composite.

NANOCOMPOSITES PREPARATION

To achieve a concentration of 1% TiO₂ (w/w) in the orthodontic adhesive, 40mg of TiO₂ NPs were added to 4000 mg of orthodontic adhesive (Enlight, Ormco Corp, CA) and blended by using a composite mixer (High Energy Ball Mill, Retsch - Emax, Centre for Nanotechnology & Centre for Excellence, Andhra University, Visakhapatnam, Andhra Pradesh, India) at a speed of 3500 revolutions per minute in dark environment for 5min. A scanning electron microscopy (SEM) examination at a magnification of 200x was performed on a cured sample, to check the uniform distribution of the TiO₂ NPs within the composite paste¹⁴14 Poosti M, Ramazanzadeh B, Zebarjad M, Javadzadeh P, Naderinasab M, Shakeri MT. Shear bond strength and antibacterial effects of orthodontic composite containing TiO2 nanoparticles. Eur J Orthod. 2013;35(5):676-9. (Fig 1).

Figure 1:
SEM image showing uniform distribution of TiO₂ NPs, at 200x magnification

For the preparation of 1% Ag (w/w) nanocomposite, the same above-mentioned procedure was followed, then a cured sample was examined on a scanning electron microscope at a magnification of 200x, to confirm the uniform distribution of Ag NPs within the composite paste (Fig 2).

Figure 2:
SEM image showing uniform distribution of Ag NPs, at 200x magnification.

PREPARATION OF SAMPLES FOR TESTING ANTIBACTERIAL ACTIVITY

A total of 800 composite discs were used for the study. The thickness of these composite discs was set to 3mm, with diameter of 6mm, using a clear transparent thermoplastic sheet (Bioplast, Libral traders, New Delhi, India), and holes of specific dimensions were made using a high-speed air rotor handpiece.

Discs prepared with the four types of composites were used to evaluate the antibacterial activities against Streptococcus mutans (MTCC 497) and Lactobacillus acidophilus (MTCC 10307).

EVALUATION OF ANTIBACTERIAL ACTIVITY

Disk agar diffusion test (DAD)

This test determines the ability of antibacterial agents to diffuse within agar and produce a bacterial inhibition zone. The composite discs (n=4) were placed on the Mueller-Hinton agar (MHA) plate, at a distance of 2 cm from each other, and then 20 µL from the bacterial suspensions (?10⁸8 Al-Nafori MK, Elshal MG, Refai WM. The effect of incorporating gold and silver nanoparticles in orthodontic adhesive system on bond strength of orthodontic bracket. EC Dent Sci. 2017;11(4):119-131. CFU/ml) were spread, whose density was adjusted with sterile phosphate buffer saline (PBS) to match its density to 0.5 in McFarland scale.

After 48 hours of incubation, the bacterial growth inhibition diameter for both S. mutans and L. acidophilus was measured using an inhibition zone measuring scale (Figs 3 and 4).

Figure 3:
Bacterial growth inhibition zones for S. mutans, using DAD test.

Figure 4:
Bacterial growth inhibition zones for L. acidophilus, using DAD test.

Biofilm inhibition test

Three-day biofilms were generated on composite discs (n=4) using flat-bottom 96-well microtiter plates (TCP177), which were later inoculated with the adjusted bacterial inoculum. Once the 10 µL of bacterial suspension was added, biofilms were incubated at a temperature of 37°C for 72 h. At the end of the third day, composite discs were removed and rinsed thoroughly with sterilized saline, to wash out the planktonic and loosely attached cells. Finally, in order to dislodge biofilms, all the composite discs were immersed in 1ml BHI broth and vortexed for 1 min. The CFUs/mm²2 Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7. of test wells were calculated using the Miles et al.¹⁵15 Miles AA, Misra SS, Irwin JO. The estimation of the bactericidal power of the blood. J Hyg (Lond).1938;38(6):732-49. method.

Antibacterial properties of eluted components

The discs were immersed in tubes containing 5 ml of BHI broth at 37°C. Discs were removed, and liquid media were transferred to new plastic tubes after 2 hours, 3 days and 30 days. The density of the bacterial suspension was adjusted to match 0.5 in the McFarland scale (≈10⁸8 Al-Nafori MK, Elshal MG, Refai WM. The effect of incorporating gold and silver nanoparticles in orthodontic adhesive system on bond strength of orthodontic bracket. EC Dent Sci. 2017;11(4):119-131. CFU/ml). Fifty microliters of bacterial suspension (in a final concentration of 2.5 × 10⁵5 Al-Eesa NA, Wong FS, Johal A, Hill RG. Fluoride containing bioactive glass composite for orthodontic adhesives-ion release properties. Dent Mater. 2017;33(11):1324-9. CFU/ml) were added to the previous tubes, and tubes were agitated at 300 rpm for 24 h at 37°C. The CFUs/ml of test wells were calculated using the Miles et al.¹⁵15 Miles AA, Misra SS, Irwin JO. The estimation of the bactericidal power of the blood. J Hyg (Lond).1938;38(6):732-49. method.

EVALUATION OF SHEAR BOND STRENGTH

Eighty premolars freshly extracted for orthodontic treatment purposes were divided into four groups of 20 teeth each. The inclusion criteria for tooth selection was: anatomically and morphologically well-defined extracted premolars, with intact buccal enamel surface, and without any developmental defects, enamel caries, or fractured crowns. Then the samples were mounted in cold-cure acrylic resin poured in PVC tubes. The teeth were vertically embedded in acrylic up to the cemento-enamel junction (CEJ), and standard bonding procedure was carried out.

The buccal surface of the tooth was etched using 37% phosphoric acid (Eazetech, Anabond) for 30 seconds, rinsed thoroughly with running water for 30 seconds, and gently dried with air spray. A thin coat of primer (Orthosolo, Ormco, CA) was then applied with applicator tip and light-cured for 10 secs, followed by bonding of MBT 0.022-in stainless steel premolar brackets (Ortho Organizers) with the four types of orthodontic adhesives, light-cured for 40 seconds (10 seconds on each side). While bonding the brackets to the tooth surface, a 300-g force was applied for approximately 5 seconds, to ensure a uniform thickness of the adhesive, measured with a dynamometer (Dial tension gauge, MISUMI INDIA Pvt Ltd, Haryana, India). Excessive adhesive was removed with a probe. After completion of the bonding procedure, the teeth were immersed in a container with distilled water, for 24 hours.

Eighty samples from each of the four groups were subjected to a shear bond strength test, using an universal testing machine (Instron, model 8801). Testing was performed at a crosshead speed of 1mm/minute. The values obtained for the force required to shear the bracket, causing bond failure, were recorded in Mega Pascals (MPa).

STATISTICAL ANALYSIS

Shear bond strength results were analyzed using Kruskal-Wallis test, as the standard deviation values were not less than half of the mean value, which means the data did not follow normal distribution. The results of the antibacterial tests have been analyzed using one-away ANOVA, followed by Tukey’s post-hoc test, used to find statistical significant differences between and within the groups. A p-value of less than 0.05 (p<0.05) was considered statistically significant, at a 95% confidence interval.

RESULTS

DISK AGAR DIFFUSION TEST

Statistically significant difference was seen in the mean antibacterial activity against both S. mutans and L. acidophilus. The mean diameter of bacterial inhibition zone showed that the silver group (Group III) presented the highest mean, and it was reduced for titanium group (Group II), followed by fluoride group (Group IV) and the control group (Group I) (Table 1).

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Table 1:
Comparison of disk agar diffusion test (mm) between the groups.

BIOFILM INHIBITION TEST

Significant difference (p<0.05) was seen in mean bacterial colony count (CFU/mm²2 Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7.) in both S. mutans and L. acidophilus. The silver group (Group III) showed the lowest mean bacterial colony count, followed by the titanium group (Group II) ; and the mean bacterial colony count was increased in both the fluoride (Group IV) and control groups (Group I) (Table 2).

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Table 2:
Comparison of colony count (CFU/mm²2 Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7.) of Streptococcus mutans and Lactobacillus acidophilus between the groups, in biofilm inhibition test.

ELUTED COMPONENT TEST

Significant difference was seen in the mean antibacterial activity for all groups, except on Day 0, when a significant reduction was observed in the colony count (CFU/ml) for all the groups from day 0 to day 3. A subsequent rise in colony count was seen between days 3 and 30, but comparatively the colony count on day 30 was less than that observed on day 0, except for the control group (Tables 3 and 4).

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Table 3:
Comparison of colony count (CFU/ml) of S. mutans between groups and time points in eluted component test.

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Table 4:
Comparison of colony count (CFU/ml) of L. acidophilus between groups and time points in eluted component test.

SHEAR BOND STRENGTH

Statistically significant difference (p<0.005) was seen in mean shear bond strength values of all the groups. The mean SBS of the control group was the highest among the groups, followed by the fluoride, titanium, and silver groups (Table 5).

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Table 5:
Comparison of shear bond strength (MPa) between groups.

DISCUSSION

Decades since its introduction, composite resin adhesives remain the first choice of most orthodontists for bonding brackets; however, they may facilitate demineralization of adjacent enamel. Some of their shortcomings have not been eliminated yet. De Soet and De Graaff ¹⁶16 De Soet JJ, De Graaff J. Microbiology of carious lesions. Dent Update. 1998;25(8):319-24. suggested that Streptococcus mutans is the main bacteria responsible for enamel demineralization.

Various anti-bacterial agents have been incorporated into the orthodontic adhesives to increase their antibacterial activity.¹⁷17 Wilson RM, Donly KJ. Demineralization around orthodontic brackets bonded with resin-modified glass ionomer cement and fluoride-releasing resin composite. Pediatr Dent. 2001;23(3):255-9.^,¹⁸18 Cohen WJ, Wiltshire WA, Dawes C, Lavelle CL. Long-term in vitro fluoride release and rerelease from orthodontic bonding materials containing fluoride. Am J Orthod Dentofacial Orthop. 2003;124(5):571-6. But few studies¹⁹19 Zanarini M, Pazzi E, Bonetti S, Ruggeri O, Bonetti GA, Prati C. In vitro evaluation of the effects of a fluoride-releasing composite on enamel demineralization around brackets. Prog Orthod. 2012;13(1):10-6.^,²⁰20 Dubroc Jr GC, Mayo JA, Rankine CA. Reduction of caries and of demineralization around orthodontic brackets: effect of a fluoride-releasing resin in the rat model. Am J Orthod Dentofacial Orthop. 1994;106(6):583-7. have reported lower bond strength with the use of fluoride-releasing composite resins for bonding orthodontic attachments, for preventing demineralization.

With the advent of nanotechnology, and their excellent properties in orthodontic bonding, NPs have been widely used in biological and pharmaceutical applications. Kim et al.²¹21 Kim JS, Kuk E, Yu KN, Kim JH, Park SJ, Lee HJ. Antimicrobial effects of silver nanoparticles. Nanomedicine. 2007;3(1):95-101. concluded that NPs and their ions can produce free radicals, resulting in the induction of oxidative stress (i.e., reactive oxygen species; ROS); the produced ROS can irreversibly damage bacteria (e.g. their membrane, DNA, and mitochondria), resulting in bacterial death.

Various authors have demonstrated that the incorporation of nanoparticles into the orthodontic adhesives affects their shear bond strength. However, an increase in its concentration has been considered cytotoxic.²²22 Miura N, Shinohara Y. Cytotoxic effect and apoptosis induction by silver nanoparticles in HeLa cells. Biochem Biophys Res Commun. 2009;390(3):733-37.^,²³23 Prabhu S, Poulose EK. Silver nanoparticles: mechanism of antimicrobial action, synthesis, medical applications, and toxicity effects. Int Nano Lett. 2012;2(1):32.

Nanoparticles are known for their antimicrobial properties because of their small size and increased surface area.²⁴24 Ozak ST, Ozkan P. Nanotechnology and dentistry. Eur J Dent. 2013;7(1):145. They are also insoluble with a size smaller than 100nm.⁹9 Salehi P, Babanouri N, Roein-Peikar M, Zare F. Long-term antimicrobial assessment of orthodontic brackets coated with nitrogen-doped titanium dioxide against Streptococcus mutans. Prog Orthod. 2018;19(1):35. In this present study, a concentration of 1.0% w/w NPs was added to the orthodontic adhesives, as the small particle size and large surface area enables them to release more ions at a low filler level without being cytotoxic.

Antibacterial activity

Disc agar diffusion test has shown significant growth inhibition zones against S. mutans and L. acidophilus with modified composites containing 1% w/w silver nanoparticles, 1% w/w TiO₂ nanoparticles, when compared with fluoride-releasing and conventional composites. In the biofilm inhibition test, when the colony count (CFU/mm²2 Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7.) was calculated, the Ag group showed the highest antibacterial activity among all the four groups. Antibacterial properties of eluted components against Streptococcus mutans and Lactobacillus acidophilus at regular intervals of time showed a significant reduction in colony count (CFU/ml) of bacteria for the first three days in NPs-modified composites. Later a subsequent increase in colony count (CFU/ml) was observed from day 3 to day 30 in all the three experimental groups.

This study demonstrated that 1% (w/w) Ag NPs have the highest antibacterial effect, which was in agreement with the results of the study conducted by Kassaee et al.²⁵25 Kassaee MZ, Akhavan A, Sheikh N, Sodagar A. Antibacterial effects of a new dental acrylic resin containing silver nanoparticles. J App Polymer Sci. 2008;110(3):1699-1703.

Ag NPs have peculiar chemical, physical and biological properties, compared to those of traditional bulk materials. Their small particle size along with large surface area provide much more efficacious antibacterial properties.¹²12 Naslapur S, Malik SA, Laxmikanth SM, Ramachandra CS. The effect of silver oxide nanoparticles on the antibacterial property and shear bond strength of dental composite. Dent Health Curr Res. 2019;5(1). The reason behind reduced bacterial adhesion might be the reduced surface free energy (SFE).

The results of the present study demonstrated that 1% (w/w) TiO₂ NPs significantly reduced bacterial growth, which is in agreement with the results of Sodagar et al.²⁶26 Sodagar A, Akhoundi MS, Bahador A, Jalali YF, Behzadi Z, Elhaminejad F, et al. Effect of TiO2 nanoparticles incorporation on antibacterial properties and shear bond strength of dental composite used in orthodontics. Dental Press J Orthod. 2017;22(5):67-74.

Fluoride-releasing composite showed statistically significant antibacterial activity, compared to the control group, and the results correlate with those of the study conducted by Swapna et al.²⁷27 Swapna G, Sharma S, Soni VP, Tamgadge S. Demineralization adjacent to orthodontic brackets with fluoride releasing and conventional bonding agents. Indian J Dent Res. 2016;27(4):426-32., which stated that the fluoride-releasing composite exhibit significant inhibition of demineralization, compared to the conventional bonding agents.

Shear bond strength

In this study, the SBS of orthodontic adhesives modified with 1% (w/w) Ag NPs or 1% (w/w) TiO₂ NPs, fluoride-releasing composite (Light Bond, Reliance Orthodontic Products) and the control group was compared.

It was observed that the mean SBS values of 1% (w/w) Ag NPs and 1% (w/w) TiO₂ NPs groups were decreased, when compared with the fluoride-releasing composite and the control group. Though both silver and titanium nanoparticles were added in the same concentration in this study, the Ag group showed a significant decrease in SBS, compared to TiO₂ group. Akhavan et al.¹³13 Akhavan A, Sodagar A, Mojtahedzadeh F, Sodagar K. Investigating the effect of incorporating nanosilver/nanohydroxyapatite particles on the shear bond strength of orthodontic adhesives. Acta Odontol Scand. 2013;71(5):1038-42. evaluated that a decrease in bond strength associated with the addition of silver NPs could be due to the agglomeration of particles, creating defect points, and interfering with the curing process of the adhesive.

According to Reynolds²⁸28 Reynolds IR. A review of direct orthodontic bonding. Br J Orthod. 1975;2(3):171-8., the clinically acceptable range for SBS is 6 to 8 MPa. The present study showed that the mean SBS values of the experimental groups was greater than the clinically acceptable range, but smaller then the control group (18 to 20 MPa), which was in agreement with the study conducted by Reddy et al.²⁹29 Reddy AK, Kambalyal PB, Patil SR, Vankhre M, Khan MY, Kumar TR. Comparative evaluation and influence on shear bond strength of incorporating silver, zinc oxide, and titanium dioxide nanoparticles in orthodontic adhesive. J Orthod Sci. 2016;5(4):127-31.

Pseiner et al.³⁰30 Pseiner BC, Freudenthaler J, Jonke E, Bantleon HP. Shear bond strength of fluoride-releasing orthodontic bonding and composite materials. Eur J Orthod. 2010;32(3):268-73. reported that SBS of fluoride-releasing composite had provided sufficient mean bond strength, which was still less than the control group, and it may be used as an additional prophylactic measure in orthodontic therapy, which supports the results of the present study.

CONCLUSION

Incorporating antibacterial agents like silver and titanium dioxide nanoparticles into the orthodontic adhesives has improved their antibacterial activity better than the commercially available fluoride-releasing and the conventional composites. However, there is a significant difference in the antibacterial activity and shear bond strength of nanocomposites. The Ag nanocomposite showed statistically significant better antibacterial activity than the TiO₂ nanocomposite.

There was a statistically significant difference in mean SBS values among the four groups. The control group showed the highest SBS, followed by fluoride, titanium, and silver groups.

REFERENCES

¹
Altmann AS, Collares FM, Leitune VC, Samuel SM. The effect of antimicrobial agents on bond strength of orthodontic adhesives: a meta-analysis of in vitro studies. Orthod Craniofac Res. 2016;19(1):1-9.
²
Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7.
³
Manfred L, Covell DA, Crowe JJ, Tufekci E, Mitchell JC. A novel biomimetic orthodontic bonding agent helps prevent white spot lesions adjacent to brackets. Angle Orthod. 2013;83(1):97-103.
⁴
Papaioannou W, Gizani S, Nassika M, Kontou E, Nakou M. Adhesion of Streptococcus mutans to different types of brackets. Angle Orthod. 2007;77(6):1090-5.
⁵
Al-Eesa NA, Wong FS, Johal A, Hill RG. Fluoride containing bioactive glass composite for orthodontic adhesives-ion release properties. Dent Mater. 2017;33(11):1324-9.
⁶
Govindankutty D. Applications of nanotechnology in orthodontics and its future implications: a review. Int J Appl Dent Sci. 2015;1(4):166-71.
⁷
Hernández-Sierra JF, Ruiz F, Pena DC, Martínez-Gutiérrez F, Martínez AE, Guillén AD, et al. The antimicrobial sensitivity of Streptococcus mutans to nanoparticles of silver, zinc oxide, and gold. Nanomedicine2008;4(3):237-40.
⁸
Al-Nafori MK, Elshal MG, Refai WM. The effect of incorporating gold and silver nanoparticles in orthodontic adhesive system on bond strength of orthodontic bracket. EC Dent Sci. 2017;11(4):119-131.
⁹
Salehi P, Babanouri N, Roein-Peikar M, Zare F. Long-term antimicrobial assessment of orthodontic brackets coated with nitrogen-doped titanium dioxide against Streptococcus mutans. Prog Orthod. 2018;19(1):35.
¹⁰
Elsaka SE, Hamouda IM, Swain MV. Titanium dioxide nanoparticles addition to a conventional glass-ionomer restorative: influence on physical and antibacterial properties. J Dent. 2011;39(9):589-98.
¹¹
Sodagar A, Akhavan A, Hashemi E, Arab S, Pourhajibagher M, Sodagar K, et al. Evaluation of the antibacterial activity of a conventional orthodontic composite containing silver/hydroxyapatite nanoparticles. Prog Orthod. 2016;17(1):40.
¹²
Naslapur S, Malik SA, Laxmikanth SM, Ramachandra CS. The effect of silver oxide nanoparticles on the antibacterial property and shear bond strength of dental composite. Dent Health Curr Res. 2019;5(1).
¹³
Akhavan A, Sodagar A, Mojtahedzadeh F, Sodagar K. Investigating the effect of incorporating nanosilver/nanohydroxyapatite particles on the shear bond strength of orthodontic adhesives. Acta Odontol Scand. 2013;71(5):1038-42.
¹⁴
Poosti M, Ramazanzadeh B, Zebarjad M, Javadzadeh P, Naderinasab M, Shakeri MT. Shear bond strength and antibacterial effects of orthodontic composite containing TiO2 nanoparticles. Eur J Orthod. 2013;35(5):676-9.
¹⁵
Miles AA, Misra SS, Irwin JO. The estimation of the bactericidal power of the blood. J Hyg (Lond).1938;38(6):732-49.
¹⁶
De Soet JJ, De Graaff J. Microbiology of carious lesions. Dent Update. 1998;25(8):319-24.
¹⁷
Wilson RM, Donly KJ. Demineralization around orthodontic brackets bonded with resin-modified glass ionomer cement and fluoride-releasing resin composite. Pediatr Dent. 2001;23(3):255-9.
¹⁸
Cohen WJ, Wiltshire WA, Dawes C, Lavelle CL. Long-term in vitro fluoride release and rerelease from orthodontic bonding materials containing fluoride. Am J Orthod Dentofacial Orthop. 2003;124(5):571-6.
¹⁹
Zanarini M, Pazzi E, Bonetti S, Ruggeri O, Bonetti GA, Prati C. In vitro evaluation of the effects of a fluoride-releasing composite on enamel demineralization around brackets. Prog Orthod. 2012;13(1):10-6.
²⁰
Dubroc Jr GC, Mayo JA, Rankine CA. Reduction of caries and of demineralization around orthodontic brackets: effect of a fluoride-releasing resin in the rat model. Am J Orthod Dentofacial Orthop. 1994;106(6):583-7.
²¹
Kim JS, Kuk E, Yu KN, Kim JH, Park SJ, Lee HJ. Antimicrobial effects of silver nanoparticles. Nanomedicine. 2007;3(1):95-101.
²²
Miura N, Shinohara Y. Cytotoxic effect and apoptosis induction by silver nanoparticles in HeLa cells. Biochem Biophys Res Commun. 2009;390(3):733-37.
²³
Prabhu S, Poulose EK. Silver nanoparticles: mechanism of antimicrobial action, synthesis, medical applications, and toxicity effects. Int Nano Lett. 2012;2(1):32.
²⁴
Ozak ST, Ozkan P. Nanotechnology and dentistry. Eur J Dent. 2013;7(1):145.
²⁵
Kassaee MZ, Akhavan A, Sheikh N, Sodagar A. Antibacterial effects of a new dental acrylic resin containing silver nanoparticles. J App Polymer Sci. 2008;110(3):1699-1703.
²⁶
Sodagar A, Akhoundi MS, Bahador A, Jalali YF, Behzadi Z, Elhaminejad F, et al. Effect of TiO2 nanoparticles incorporation on antibacterial properties and shear bond strength of dental composite used in orthodontics. Dental Press J Orthod. 2017;22(5):67-74.
²⁷
Swapna G, Sharma S, Soni VP, Tamgadge S. Demineralization adjacent to orthodontic brackets with fluoride releasing and conventional bonding agents. Indian J Dent Res. 2016;27(4):426-32.
²⁸
Reynolds IR. A review of direct orthodontic bonding. Br J Orthod. 1975;2(3):171-8.
²⁹
Reddy AK, Kambalyal PB, Patil SR, Vankhre M, Khan MY, Kumar TR. Comparative evaluation and influence on shear bond strength of incorporating silver, zinc oxide, and titanium dioxide nanoparticles in orthodontic adhesive. J Orthod Sci. 2016;5(4):127-31.
³⁰
Pseiner BC, Freudenthaler J, Jonke E, Bantleon HP. Shear bond strength of fluoride-releasing orthodontic bonding and composite materials. Eur J Orthod. 2010;32(3):268-73.

Publication Dates

Publication in this collection
07 Nov 2022
Date of issue
2022

History

Received
19 Mar 2020
Accepted
15 Mar 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Altmann AS, Collares FM, Leitune VC, Samuel SM. The effect of antimicrobial agents on bond strength of orthodontic adhesives: a meta-analysis of in vitro studies. Orthod Craniofac Res. 2016;19(1):1-9.

[2] ²
Borzabadi-Farahani A, Borzabadi E, Lynch E. Nanoparticles in orthodontics, a review of antimicrobial and anti-caries applications. Acta Odontol Scand. 20141;72(6):413-7.

[3] ³
Manfred L, Covell DA, Crowe JJ, Tufekci E, Mitchell JC. A novel biomimetic orthodontic bonding agent helps prevent white spot lesions adjacent to brackets. Angle Orthod. 2013;83(1):97-103.

[4] ⁴
Papaioannou W, Gizani S, Nassika M, Kontou E, Nakou M. Adhesion of Streptococcus mutans to different types of brackets. Angle Orthod. 2007;77(6):1090-5.

[5] ⁵
Al-Eesa NA, Wong FS, Johal A, Hill RG. Fluoride containing bioactive glass composite for orthodontic adhesives-ion release properties. Dent Mater. 2017;33(11):1324-9.

[6] ⁶
Govindankutty D. Applications of nanotechnology in orthodontics and its future implications: a review. Int J Appl Dent Sci. 2015;1(4):166-71.

[7] ⁷
Hernández-Sierra JF, Ruiz F, Pena DC, Martínez-Gutiérrez F, Martínez AE, Guillén AD, et al. The antimicrobial sensitivity of Streptococcus mutans to nanoparticles of silver, zinc oxide, and gold. Nanomedicine2008;4(3):237-40.

[8] ⁸
Al-Nafori MK, Elshal MG, Refai WM. The effect of incorporating gold and silver nanoparticles in orthodontic adhesive system on bond strength of orthodontic bracket. EC Dent Sci. 2017;11(4):119-131.

[9] ⁹
Salehi P, Babanouri N, Roein-Peikar M, Zare F. Long-term antimicrobial assessment of orthodontic brackets coated with nitrogen-doped titanium dioxide against Streptococcus mutans. Prog Orthod. 2018;19(1):35.

[10] ¹⁰
Elsaka SE, Hamouda IM, Swain MV. Titanium dioxide nanoparticles addition to a conventional glass-ionomer restorative: influence on physical and antibacterial properties. J Dent. 2011;39(9):589-98.

[11] ¹¹
Sodagar A, Akhavan A, Hashemi E, Arab S, Pourhajibagher M, Sodagar K, et al. Evaluation of the antibacterial activity of a conventional orthodontic composite containing silver/hydroxyapatite nanoparticles. Prog Orthod. 2016;17(1):40.

[12] ¹²
Naslapur S, Malik SA, Laxmikanth SM, Ramachandra CS. The effect of silver oxide nanoparticles on the antibacterial property and shear bond strength of dental composite. Dent Health Curr Res. 2019;5(1).

[13] ¹³
Akhavan A, Sodagar A, Mojtahedzadeh F, Sodagar K. Investigating the effect of incorporating nanosilver/nanohydroxyapatite particles on the shear bond strength of orthodontic adhesives. Acta Odontol Scand. 2013;71(5):1038-42.

[14] ¹⁴
Poosti M, Ramazanzadeh B, Zebarjad M, Javadzadeh P, Naderinasab M, Shakeri MT. Shear bond strength and antibacterial effects of orthodontic composite containing TiO2 nanoparticles. Eur J Orthod. 2013;35(5):676-9.

[15] ¹⁵
Miles AA, Misra SS, Irwin JO. The estimation of the bactericidal power of the blood. J Hyg (Lond).1938;38(6):732-49.

[16] ¹⁶
De Soet JJ, De Graaff J. Microbiology of carious lesions. Dent Update. 1998;25(8):319-24.

[17] ¹⁷
Wilson RM, Donly KJ. Demineralization around orthodontic brackets bonded with resin-modified glass ionomer cement and fluoride-releasing resin composite. Pediatr Dent. 2001;23(3):255-9.

[18] ¹⁸
Cohen WJ, Wiltshire WA, Dawes C, Lavelle CL. Long-term in vitro fluoride release and rerelease from orthodontic bonding materials containing fluoride. Am J Orthod Dentofacial Orthop. 2003;124(5):571-6.

[19] ¹⁹
Zanarini M, Pazzi E, Bonetti S, Ruggeri O, Bonetti GA, Prati C. In vitro evaluation of the effects of a fluoride-releasing composite on enamel demineralization around brackets. Prog Orthod. 2012;13(1):10-6.

[20] ²⁰
Dubroc Jr GC, Mayo JA, Rankine CA. Reduction of caries and of demineralization around orthodontic brackets: effect of a fluoride-releasing resin in the rat model. Am J Orthod Dentofacial Orthop. 1994;106(6):583-7.

[21] ²¹
Kim JS, Kuk E, Yu KN, Kim JH, Park SJ, Lee HJ. Antimicrobial effects of silver nanoparticles. Nanomedicine. 2007;3(1):95-101.

[22] ²²
Miura N, Shinohara Y. Cytotoxic effect and apoptosis induction by silver nanoparticles in HeLa cells. Biochem Biophys Res Commun. 2009;390(3):733-37.

[23] ²³
Prabhu S, Poulose EK. Silver nanoparticles: mechanism of antimicrobial action, synthesis, medical applications, and toxicity effects. Int Nano Lett. 2012;2(1):32.

[24] ²⁴
Ozak ST, Ozkan P. Nanotechnology and dentistry. Eur J Dent. 2013;7(1):145.

[25] ²⁵
Kassaee MZ, Akhavan A, Sheikh N, Sodagar A. Antibacterial effects of a new dental acrylic resin containing silver nanoparticles. J App Polymer Sci. 2008;110(3):1699-1703.

[26] ²⁶
Sodagar A, Akhoundi MS, Bahador A, Jalali YF, Behzadi Z, Elhaminejad F, et al. Effect of TiO2 nanoparticles incorporation on antibacterial properties and shear bond strength of dental composite used in orthodontics. Dental Press J Orthod. 2017;22(5):67-74.

[27] ²⁷
Swapna G, Sharma S, Soni VP, Tamgadge S. Demineralization adjacent to orthodontic brackets with fluoride releasing and conventional bonding agents. Indian J Dent Res. 2016;27(4):426-32.

[28] ²⁸
Reynolds IR. A review of direct orthodontic bonding. Br J Orthod. 1975;2(3):171-8.

[29] ²⁹
Reddy AK, Kambalyal PB, Patil SR, Vankhre M, Khan MY, Kumar TR. Comparative evaluation and influence on shear bond strength of incorporating silver, zinc oxide, and titanium dioxide nanoparticles in orthodontic adhesive. J Orthod Sci. 2016;5(4):127-31.

[30] ³⁰
Pseiner BC, Freudenthaler J, Jonke E, Bantleon HP. Shear bond strength of fluoride-releasing orthodontic bonding and composite materials. Eur J Orthod. 2010;32(3):268-73.

	Group	n	Mean	SD	p-value
S. mutans	Group I	20	0.0000^#	0.000	< 0.001
	Group II	20	6.850^#	1.69
	Group III	20	10.85^#	2.94
	Group IV	20	4.700^#	2.51
L. acidophilus	Group I	20	0.0000^#	0.000	< 0.001
	Group II	20	7.3000^#	1.78
	Group III	20	10.700^#	1.49
	Group IV	20	4.150^#	2.87

	Group	n	Mean	SD	p-value
S. mutans	Group I	20	899.30*	134.12	< 0.001
	Group II	20	454.60*	176.51
	Group III	20	315.70	127.39
	Group IV	20	678.45	91.288
L. acidophilus	Group I	20	870.00*	109.88	< 0.001
	Group II	20	440.85#	106.48
	Group III	20	323.05#	189.30
	Group IV	20	644.55*	177.95

Day	Group	n	Mean	SD	p-value
0	Group I	20	2.310	0.126	0.25
	Group II	20	2.186	0.409
	Group III	20	2.202	0.337
	Group IV	20	2.225	0.207
3	Group I	20	2.405	0.102	< 0.001
	Group II	20	1.908*	0.202
	Group III	20	1.765	0.209
	Group IV	20	2.060*	0.405
30	Group I	20	2.680	0.128	< 0.001
	Group II	20	2.017*	0.207
	Group III	20	1.922*	0.237
	Group IV	20	2.105	0.391

Day	Group	n	Mean	SD	p-value
0	Group I	20	2.1040	0.138	0.32
	Group II	20	1.9205	0.242
	Group III	20	1.8155	0.288
	Group IV	20	2.0880	0.231
3	Group I	20	2.2095	0.135	< 0.001
	Group II	20	1.6110*	0.224
	Group III	20	1.5630*^#	0.243
	Group IV	20	1.8305^#	0.241
30	Group I	20	2.4165	0.136	< 0.001
	Group II	20	1.7150*	0.221
	Group III	20	1.6465^#	0.256
	Group IV	20	1.9320^#*	0.268

Group	n	Mean	SD	p- value
Group I	20	24.679#	6.400	0.005
Group II	20	17.177#	8.349
Group III	20	14.694#	6.688
Group IV	20	20.872#	9.869

Brasil

Brasil

Evaluation of antibacterial properties and shear bond strength of orthodontic composites containing silver nanoparticles, titanium dioxide nanoparticles and fluoride: An in vitro study

ABSTRACT

Objective:

Materials and Methods:

Results:

Conclusion:

RESUMO

Objetivo:

Métodos:

Resultados:

Conclusão:

INTRODUCTION

MATERIAL AND METHODS

Nanoparticles used for the study

Adhesives used for the study

Media used for bacterial culture

Types of bacterial strains used

Equipment used

Methodology

NANOCOMPOSITES PREPARATION

PREPARATION OF SAMPLES FOR TESTING ANTIBACTERIAL ACTIVITY

EVALUATION OF ANTIBACTERIAL ACTIVITY

Disk agar diffusion test (DAD)

Biofilm inhibition test

Antibacterial properties of eluted components

EVALUATION OF SHEAR BOND STRENGTH

STATISTICAL ANALYSIS

RESULTS

DISK AGAR DIFFUSION TEST

BIOFILM INHIBITION TEST

ELUTED COMPONENT TEST

SHEAR BOND STRENGTH

DISCUSSION

Antibacterial activity

Shear bond strength

CONCLUSION

REFERENCES

Publication Dates

History