|Year : 2021 | Volume
| Issue : 1 | Page : 21
Surface characterization and frictional force between stainless steel brackets and archwires in orthodontic patients using chlorhexidine- and Persica-containing mouthrinses: A randomized controlled trial
Elham-Sadat Emadian Razavi1, Tahereh Hosseinzadeh Nik2, Tabassom Hooshmand3, Habibeh Farazdaghi4, Arian Hesam Arefi5
1 Orthodontist, Private Practice, Dental Research Center, Dentistry Research Institute, School of Dentistry, Tehran University of Medical Sciences, Tehran, Iran
2 Department of Orthodontics, Dental Research Center, Dentistry Research Institute, School of Dentistry, Tehran University of Medical Sciences, Tehran, Iran
3 Department of Dental Biomaterials, School of Dentistry/Research Center for Science and Technology in Medicine, Tehran University of Medical Sciences, Tehran, Iran
4 Department of Oral and Maxillofacial Radiologist, Private Practice, Tehran, Iran
5 Dental Research Center, Zahedan University of Medical Sciences, Zahedan, Iran
|Date of Submission||13-Jul-2019|
|Date of Acceptance||03-May-2020|
|Date of Web Publication||06-Apr-2021|
Dr. Tabassom Hooshmand
Department of Dental Biomaterials, School of Dentistry/Research Center for Science and Technology in Medicine, Tehran University of Medical Sciences, North Kargar Street, Tehran 14174
Source of Support: None, Conflict of Interest: None
Background: The aim of this study was to compare the effect of chlorhexidine- and Persica-containing mouthrinses on the surface characterization of orthodontic appliance and friction between the orthodontic stainless steel wires and brackets.
Materials and Methods: In this randomized controlled trial, 75 orthodontic patients (aged 13–30) were allocated (n = 25) into two experimental groups (prescribed by Persica- or chlorhexidine-containing mouthrinse) and one control group (no prescription). The ovoid stainless steel archwires were placed, and the maxillary first premolar stainless steel edgewise brackets were ligated to wires by elastomeric rings. The patients were recalled after 2 weeks, and then, the archwires were removed and replaced. The surface analysis of archwires and brackets was evaluated using scanning electron microscopy and atomic force microscopy. The frictional forces between the archwires and brackets were measured using a universal testing machine. The data for surface roughness were analyzed by the nonparametric Kruskal–Wallis and Mann–Whitney tests. The frictional forces data were analyzed using a two-way analysis of variance and Tukey's post hoc test using SPSS software. The level of significance was P < 0.05.
Results: The retrieved brackets showed minor changes in their surface topography. The surface roughness of archwires after the intervention was significantly greater for the chlorhexidine than that of Persica (P < 0.05). The friction force between the archwires and brackets was also significantly higher for the chlorhexidine than that of Persica (P < 0.05).
Conclusion: The Persica-containing mouthrinse from the biomechanical and biochemical standpoints may be a better option for oral hygiene in orthodontic patients compared with the chlorhexidine.
Keywords: Friction, mouthrinse, orthodontic bracket, surface, wire
|How to cite this article:|
Razavi ESE, Nik TH, Hooshmand T, Farazdaghi H, Arefi AH. Surface characterization and frictional force between stainless steel brackets and archwires in orthodontic patients using chlorhexidine- and Persica-containing mouthrinses: A randomized controlled trial. Dent Res J 2021;18:21
|How to cite this URL:|
Razavi ESE, Nik TH, Hooshmand T, Farazdaghi H, Arefi AH. Surface characterization and frictional force between stainless steel brackets and archwires in orthodontic patients using chlorhexidine- and Persica-containing mouthrinses: A randomized controlled trial. Dent Res J [serial online] 2021 [cited 2021 Aug 3];18:21. Available from: https://www.drjjournal.net/text.asp?2021/18/1/21/313116
| Introduction|| |
Implementation of an individualized oral hygiene care program for every patient during orthodontic treatment is necessary to achieve successful outcome. Brushing and cleaning the teeth will become difficult when orthodontic appliances are in place. Furthermore, after bonding of orthodontic attachments, the level of Streptococcus mutans and lactobacilli increases in the oral cavity.
Chlorhexidine is a well-known mouthwash and is usually used for the treatment of gingivitis and/or periodontitis which many clinicians prescribe it for orthodontic patients. It has antiplaque effects, can inhibit the activity of acidogenic bacteria, and thus, can prevent dental caries.,, Therefore, chlorhexidine has been considered as a gold standard for testing the efficacy of other mouthrinses in most studies.,,,, On the other hand, chlorhexidine has some side effects such as tooth discoloration and sense of burning or dryness in the mouth.,
Persica is an herbal antibacterial agent; it is prepared from Salvadora persica extract and assumed useful for dental and periodontal health. Several studies have evaluated the efficacy of Persica products.,, The available literature shows that using Persica or its extract is effective in the reduction of dental plaque accumulation and bleeding on brushing, can control gingivitis and periodontal diseases, and also can reduce the number of S. mutans colonies. Therefore, it could be effective in the prevention of dental caries.,,,,,, There is some evidence that Persica and chlorhexidine are equally effective in control of gingival inflammation. However, the mouthrinses due to their ions and pH can be harmful to orthodontic appliances. Several studies have investigated the role and effect of prophylactic agents on the corrosion, mechanical properties, surface characterization of the orthodontic appliance, and the friction of sliding movement.,,,,
In the mechanical terminology, friction is a force that resists the relative motion of two objects in contact and its direction is tangential to the shared interface of the surfaces. In orthodontic practice, friction is usually an unfavorable force; it opposes the sliding mechanics of tooth movement, can disturb light continuous forces, and can destroy guided tooth movement along the archwire. However, sometimes, the orthodontist decides to burn anchorage for specific purposes and benefits from the frictional forces.
Another issue that is of much interest to be investigated is surface roughness. Surface characterization of orthodontic wires and brackets after immersion in the fluoride-containing mouthrinses has been already investigated, and the derived conclusion was that fluoride could increase the surface roughness of fixed orthodontic appliances.,,,,
Aghili et al. evaluated the effect of chlorhexidine-, fluoride-, and herbal-containing mouthwashes on the surface characterization and mechanical properties of stainless steel, nickel–titanium (NiTi), and coated archwires. They concluded that all mouthwashes changed the mechanical properties and surface quality of the orthodontic wires during treatment. Huang et al. introduced diamond-like carbon (DLC) films onto NiTi orthodontic archwires in order to protect the archwire against fluoride-induced corrosion and also to reduce the friction. Their results showed that after immersion in a high fluoride ion environment, the variation in the surface roughness was less than that of other groups. In addition, the friction tests showed that applying a DLC coating, both in ambient air and artificial saliva decreased the fretting corrosion and the coefficient of friction significantly. Hosseinzadeh Nik et al. investigated the effect of chlorhexidine-containing prophylactic agent on the surface roughness and static friction of stainless steel and NiTi wires and stainless steel brackets in vitro. They concluded that immersion in the chlorhexidine solution did not have a significant influence on the surface roughness of archwires or on the frictional resistance between brackets and archwires.
To our knowledge, the majority of the studies in this field are in vitro and laboratory-based and the clinician cannot extrapolate the obtained results to the real oral conditions. In the present study, we aimed to compare the effect of chlorhexidine and Persica-containing mouthrinses on the surface characterization of orthodontic appliance and the friction between stainless steel archwires and brackets in patients with orthodontic treatment.
| Materials and Methods|| |
This study was a randomized, parallel-group, and active-controlled trial with a 1:1 allocation ratio. The patients who were under orthodontic treatment with fixed appliances were considered. The inclusion criteria for the participants were as follows: healthy controls with no history or presence of metabolic, salivary gland, or systemic diseases, age between 13 and 30 years, and ability to control oral hygiene. The treatment plans for the patients were 2 or 4 premolar extractions, and the patients were at the phase of anterior retraction with 19 × 25 stainless steel wires. At the time of intervention, anterior retraction had not been yet started. Therefore, there was a free space on the wire at the extraction site which we ligated the brackets. The exclusion criteria were as follows: consuming medicated ions that affect the amount or consistency of saliva, consuming any other mouthrinse, smoking and drug abusing, and pregnancy or breastfeeding.
One hundred patients (between 13 and 30 years) participated in this study. By considering the exclusion criteria, 25 patients were excluded from the study. The remaining 75 patients were randomly allocated into two experimental groups (prescribed by Persica or chlorhexidine mouthrinse) and one control group with no prescription (n = 25), as shown in [Figure 1]. Written ethical consent approved by the Medical Ethics Committee of National University (ethical approval ID. IRCT2014032117067N1) was obtained from the patients according to the Declaration of Helsinki.
Three paper cards were prepared, and the letters “A,” “E,” and “L” were written on them. There are the last letters of “Persica,” “chlorhexidine,” and “control.” Each patient took the card, and the clinician gave her/him the hygienic package. When any of the groups was completed, the attributed card was removed. Patients with completely healthy gingiva without manifestation of gingivitis were excluded from the chlorhexidine group and the randomization performed again for new samples. The hygienic package contained an orthodontic toothbrush, toothpaste, and the mouthrinses for the two experimental groups.
The ovoid stainless steel archwires of 0.019 × 0.025-inch (3M Unitek, Monrovia, California, USA) were placed in the mouth, and the maxillary first premolar stainless steel edgewise brackets (Master Series, American Orthodontics Ltd., Sheboygan, WI, USA) were ligated to wires by elastomeric rings (American Orthodontics Ltd., Sheboygan, WI, USA). The bracket which we planned to analyze its surface roughness was not bonded to any tooth because, at the end of the intervention, it must have been debonded. Furthermore, the bracket became useless for friction and surface analysis during debonding. Therefore, for the prevention of inevitable changes in the bracket face during debonding, they were freely attached to the wire, as shown in [Figure 2]. It was obvious that during 2 weeks of intervention, the bracket had some movement on the wire. Thus, the segment of the wire which was approximate to the bracket was used nor for the surface characteristics neither the friction analysis. The ligation of brackets was done with orthodontic ligature gun for minimizing the bracket deformation. The brackets were ligated firmly to the archwires such that they did not move even with tongue movement. As only the slot of brackets was analyzed for surface topography evaluation, there were minimum concerns about surface deformation or alteration during ligation of brackets. It should be also noted that saliva acted as a lubricant in this clinical study.
After allocation of the patients in any of the three groups, the hygienic package instructions were given to the patients as follows:
Rinse your mouth with 30 ml (2 tablespoons) of diluted Persica herbal mouthwash (Poursina Pharmaceutical Laboratories) containing extracts of S. persica, mint, and yarrow with the main ingredients of tannin, flavonoid, calcium, fluoride, chloride, and essence (15 cc Persica and 15 cc water) twice daily (morning and night) for 30 s after brushing for 2 weeks. You must not rinse your mouth with water or mouthwashes, brush your teeth, or eat immediately after using Persica for half an hour. You should clean your teeth with Oral-B toothbrush and Crest Gum Protection toothpaste.
Rinse your mouth with 30 ml (2 tablespoons) of undiluted chlorhexidine (Behsa Laboratories, Tehran, Iran) with 0.2% chlorhexidine digluconate and 13.65% ethanol twice daily (morning and night) for 30 s after brushing for 2 weeks. You must expectorate the chlorhexidine after rinsing and must not rinse your mouth with water or mouthwashes, brush your teeth, or eat immediately after using chlorhexidine for half an hour. You should clean your teeth with Oral-B toothbrush and Crest Gum Protection toothpaste.
You should clean your teeth with Oral-B toothbrush and Crest Gum Protection toothpaste twice daily for 2 weeks.
Two weeks after using hygienic package, the patients were recalled and the archwires were removed and replaced by the same orthodontist. An attempt was made to maintain arch dimensions by replacing the wires. The retrieved brackets and archwires were cleaned with 70% ethanol and cotton roll. Three patients from the chlorhexidine group because of tooth coloration and four patients in the Persica group because of bad taste were lost. In addition, two wires and brackets in the chlorhexidine group and one in the Persica group had major scratches that made surface analysis very difficult, and thus, we decided to exclude them. In order to have similar sample size in each group, five samples from the control group were excluded.
Then, the surface roughness of stainless steel archwires was quantitatively measured by atomic force microscopy (AFM). Ten millimeters of each as-received and retrieved preformed archwire was referred for surface analysis. AFM (Dualscope/Rasterscope C26, DME, Denmark) was operated in contact mode under ambient conditions. Before surface analysis, the archwires were cleaned in acetone in an ultrasonic bath at 37°C for 10 min. Then, five points of the archwire were chosen and the measurement areas were 50 μm × 50 μm. The following parameters were used to assess the surface roughness of the archwires: Sz (average of ten highest and lowest points), Sa (arithmetical mean deviation of the surface), Sdr (developed surface area ratio), Sbi (surface bearing index), and Sq (the root-mean-square deviation).
The surface characteristics and topography of the slot floors of brackets were randomly and qualitatively analyzed using scanning electron microscopy (SEM). AFM could not be used because of the morphology and dimension of the wings and slots of brackets. Nine as-received brackets were observed by SEM. Then, the brackets were randomly allocated to three groups. After 2 weeks of intervention, any changes in the surface topography of retrieved brackets were evaluated using SEM.
The frictional forces between the archwires and brackets were measured using a universal testing machine (Zwick/Roell Z050, Germany). A custom-made fixture was designed for carrying wires, as shown in [Figure 3]. A plumb line was hanging to ensure that the bracket mount was parallel to the vertical line engraved on the steel bar base of the bracket mount assembly. A load cell was calibrated between 0 and 5 N, and the bracket was drawn through the straight portion of the archwire as the crosshead moved up over a 5-mm section of archwire at a rate of 0.5 mm/min for 10 min. Care was taken to avoid inserting torsion into the test specimen during clamping. The frictional force values were recorded, and three parameters were selected for analysis of friction:
- Static friction (Fs): The maximum force (in N) recorded before the bracket started to sliding
- Maximum dynamic friction (Fk max): The maximum force (in N) recorded in each minute during sliding
- Mean of dynamic friction (Fk mean): The maximum force (in N) recorded during sliding.
The test was repeated for five times, and the mean values were recorded for analysis. After each test, the bracket-wire complex was removed and a new assembly was placed.
The statistical analysis were carried out using SPSS 20 (SPSS Inc., Chicago, IL, USA), with a significance level of 0.05. The data for the surface roughness analysis were expressed as median and 95% confidence interval for the median. The nonparametric Kruskal–Wallis test was used to identify the statistically significant differences among groups. In addition, the Mann–Whitney test was used to analyze further significant differences between two groups. The data for the friction were analyzed using a two-way analysis of variance and Tukey's post hoc test.
| Results|| |
[Figure 4]a,[Figure 4]b,[Figure 4]c and [Figure 5]a,[Figure 5]b,[Figure 5]c show the representative SEMs of the slot floors of brackets in three test groups before and after the intervention with low and high magnifications, respectively. As-received brackets were similar in topography with no visible crack, defect, or scratches. The retrieved brackets showed minor changes in the surface topography after intervention. These minor defects in the slot floors of brackets were higher in the chlorhexidine group.
|Figure 4: Scanning electron micrographs of brackets before and after intervention at low magnification (×20). (a) Control (no mouthrinse); (b) Chlorhexidine mouthrinse, and (c) Persica mouthrinse|
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|Figure 5: Scanning electron micrographs of brackets before and after intervention at high magnification (×200). (a) Control (no mouthrinse); (b) Chlorhexidine mouthrinse, and (c) Persica mouthrinse|
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Topography images of the archwires in each group before and after intervention are shown in [Figure 6]a,[Figure 6]b,[Figure 6]c. The analysis of surface roughness parameters for the as-received archwires by AFM showed no significant difference between groups (P < 0.05). The parameters of surface roughness for the as-received and retrieved archwires are shown in [Table 1], which were significantly changed after the intervention (P < 0.05). The results showed that:
|Figure 6: Atomic force micrographs of archwires before and after intervention. (a) Control (no mouthrinse); (b) Chlorhexidine mouthrinse, and (c) Persica mouthrinse retrieved archwires before and after the intervention by mouthrinses.|
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|Table 1: Mean and standard deviations of surface roughness parameters (nm) for the as-received and retrieved archwires before and after the intervention by mouthrinses|
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- Sz in the order of control, Persica, and chlorhexidine increased
- Sa in the order of control, Persica, and chlorhexidine increased, and there was a significant difference between the value for chlorhexidine and that of two other groups (P < 0.05)
- Sdr in the order of chlorhexidine, control, and Persica increased, but there was no significant difference between groups (P > 0.05)
- Sbi in the order of control, Persica, and chlorhexidine increased, but there was no significant difference between groups (P > 0.05)
- Sq in the order of Persica, control, and chlorhexidine increased, and there was a significant difference between the value for chlorhexidine and that of two other groups (P < 0.05).
The data of friction parameters for the test groups are provided in [Table 2]. As shown, there were statistically significant differences in the Fk mean and Fk max values between the three groups (P < 0.05). The Fk mean value for the chlorhexidine group was higher than that of control and for the control group was higher than that of Persica, but the differences were not statistically significant (P > 0.05). The Fk max value for the chlorhexidine group was significantly higher than that of two other groups (P < 0.05). This value for the control group was also higher than that of the Persica group, but the difference was not significant (P > 0.05). The Fs value for the chlorhexidine group was significantly higher than that of two other groups (P < 0.05). This value (Fs) for the control group was also higher than that of the Persica group, but the difference was not significant (P > 0.05).
| Discussion|| |
This study was a clinical trial on patients under fixed orthodontic treatment. The patients who met the inclusion criteria were allocated into two experimental and one control groups. The amounts of friction between the archwires and brackets were measured after the intervention (use of mouthrinse during orthodontic treatment). In our study, we did not use placebo in the control group because placebo must be used in the form of liquid as mouthrinse by patients and even the use of distilled water or artificial saliva as placebo could have affected the viscosity and pH of their saliva. This could have been considered as another variable affecting the friction force in the control group. Therefore, we decided to exclude any other variable affecting the results in the control group and also to evaluate the real clinical condition in patients who are not using any type of mouthrinse during orthodontic treatment.
The topography of brackets and surface roughness of the wires were also measured before and after the intervention. The results showed that the extent of surface roughness for the chlorhexidine group was significantly greater than that of two other groups (P < 0.05). However, no statistically significant difference in the surface roughness between the Persica and control groups was found (P > 0.05).
With regard to the friction, a higher amount of friction for the chlorhexidine group compared with other groups was observed significantly (P < 0.05). There was lower friction for the Persica group than that of control, but the difference was not significant (P > 0.05). In another study done by Alwafe et al., the samples immersed in sodium fluoride mouthwash illustrated the highest mean friction resistance and surface roughness, followed by herbal mouthwash, and the least was for artificial saliva. In the literature, a number of articles have evaluated the effect of fluoride-containing mouthwashes on the surface roughness,, and/or the friction of orthodontic archwires and brackets. However, the effect of chlorhexidine-containing mouthwash in this regard has not been fully investigated. In a previous in vitro study, the effect of chlorhexidine on the surface characterization and friction of orthodontic wires and brackets was evaluated. The results showed that a 1.5-h immersion in the 0.2% chlorhexidine mouthrinse did not have a significant influence on the surface roughness of archwires or the frictional resistance between stainless steel brackets and the two types of orthodontic wires made of stainless steel and NiTi alloys. On the other hand, another study on the surface topography of orthodontic archwires reported that the 0.12% chlorhexidine and Peroxide-containing mouthwashes showed a higher pitting view on stainless steel and NiTi wires, respectively, compared to the Persica mouthwash. As we know, chlorhexidine molecules can be bonded to the teeth and oral mucosa, and thus, the results of an in vitro study might be different to the in vivo one. Because the presence of saliva acts as a lubricant, the laboratory studies in which the sliding mechanism is performed under dry conditions may also overestimate the resistance to friction.
Studies have investigated the effect of mouthwashes on the corrosion of orthodontic wires and brackets. In a study done by Danaei et al., the ion release of orthodontic stainless steel brackets by three types of mouthrinses was investigated. Their results showed that the nickel and chromium release for the chlorhexidine was higher than that of Persica and Oral-B mouthrinses. The authors suggested that Persica and Oral-B mouthrinses were better options for oral hygiene care in orthodontic patients. The main ingredients of Oral-B mouthrinse are cetylpyridinium chloride, methylparaben, sodium saccharin, cinnamal, propylparaben, and eugenol. Other studies have also shown greater corrosion of stainless steel and NiTi endodontic files in chlorhexidine solution. In addition, the effect of Listerine, chlorhexidine, and inorganic mouthwashes on the corrosion of two commercial NiTi archwires has been studied. The inorganic mouthwash contained alkaloid margosine, resins, gum, chlorides, fluoride, sulfur, tannins, oils, saponins, flavonoids, and calcium. Some of these ingredients are similar to that of Persica mouthwash. They concluded that the chlorhexidine mouthwash had a higher corrosion rate than that of the inorganic solution. This rate of corrosion might be due to the acidity of chlorhexidine, which is proportional to hydrogen ion concentration. Furthermore, the results of a study done by Deriaty et al. showed that chlorhexidine had the highest nickel ion release from the stainless steel brackets, followed by a herbal mouthwash. If there is a direct relationship between the corrosion and surface roughness, the results of the mentioned studies are in agreement with the results obtained in the present study.
It should be also noted that in addition to the corrosion effects on the surface roughness and sliding mechanics, esthetic and biocompatibility of orthodontic appliance should be considered. Some ions such as nickel and chromium can lead to toxic and allergic symptoms. These symptoms might be intense and short term or moderate and long term; some may be resolved and some may result in chronic problems. Finally, further in vitro and in vivo studies are required to confirm the results obtained from this study.
| Conclusion|| |
From the results obtained in this study, the surface roughness of orthodontic stainless steel archwires and the friction force between the stainless steel archwires and brackets after the intervention was significantly greater for the chlorhexidine-containing mouthrinse than that of Persica. Therefore, the Persica-containing mouthrinse from the biomechanical and biochemical standpoints may be a better option for oral hygiene in orthodontic patients.
Financial support and sponsorship
This study was funded and supported by the Deputy of Research of Tehran University of Medical Sciences.
Conflicts of interest
The authors of this manuscript declare that they have no conflicts of interest, real or perceived, financial or non-financial in this article.
| References|| |
Hickman J, Millett DT, Sander L, Brown E, Love J. Powered vs. manual tooth brushing in fixed appliance patients: A short term randomized clinical trial. Angle Orthod 2002;72:135-40.
Lundström F, Krasse B. Caries incidence in orthodontic patients with high levels of Streptococcus mutans
. Eur J Orthod 1987;9:117-21.
Emilson CG. Effect of chlorhexidine gel treatment on Streptococcus mutans
population in human saliva and dental plaque. Scand J Dent Res 1981;89:239-46.
Manchanda M, Rastogi V, Swarnkar SK, Agarwal G, Jasoria G, Kalr SM. Comparative efficacy of chlorhexidine and herbal mouth rinse in patients with gingivitis. J Adv Med Dent Sci Res 2017;5:64-8.
Gazi MI, Lambourne A, Chagla AH. The antiplaque effect of toothpaste containing Salvadora persica
compared with chlorhexidine gluconate. Clin Prev Dent 1987;9:3-8.
Rosin M, Welk A, Bernhardt O, Ruhnau M, Pitten FA, Kocher T, et al
. Effect of a polyhexamethylene biguanide mouthrinse on bacterial counts and plaque. J Clin Periodontol 2001;28:1121-6.
Haerian-Ardakani A, Rezaei M, Talebi-Ardakani M, Keshavarz Valian N, Amid R, Meimandi M, et al
. Comparison of antimicrobial effects of three different mouthwashes. Iran J Public Health 2015;44:997-1003.
Renton-Harper P, Addy M, Moran J, Doherty FM, Newcombe RG. A comparison of chlorhexidine, cetylpyridinium chloride, triclosan, and C31G mouthrinse products for plaque inhibition. J Periodontol 1996;67:486-9.
Almas K. The effect of Salvadora persica
extract (miswak) and chlorhexidine gluconate on human dentin: A SEM study. J Contemp Dent Pract 2002;3:27-35.
Anderson GB, Bowden J, Morrison EC, Caffesse RG. Clinical effects of chlorhexidine mouthwashes on patients undergoing orthodontic treatment. Am J Orthod Dentofacial Orthop 1997;111:606-12.
Leyes Borrajo JL, Garcia VL, Lopez CG, Rodriguez-Nuñez I, Garcia FM, Gallas TM. Efficacy of chlorhexidine mouthrinses with and without alcohol: A clinical study. J Periodontol 2002;73:317-21.
Bishara SE, Damon PL, Olsen ME, Jakobsen JR. Effect of applying chlorhexidine antibacterial agent on the shear bond strength of orthodontic brackets. Angle Orthod 1996;66:313-6.
Kalessi A, Pack A, Thomson W, Tomkins G. An in vitro
study of the plaque control efficacy of persica: A commercially available herbal mouthwash containing extracts of Salvadora persica
. Int Dent J 2004;54:279-83.
Al lafi T, Ababneh H. The effect of the extract of the miswak (chewing sticks) used in Jordan and the Middle East on oral bacteria. Int Dent J 1995;45:218-22.
Al-Otaibi M, Al-Harthy M, Gustafsson A, Johansson A, Claesson R, Angmar-Månsson B. Subgingival plaque microbiota in Saudi Arabians after use of miswak chewing stick and toothbrush. J Clin Periodontol 2004;31:1048-53.
Darout IA, Albandar JM, Skaug N. Periodontal status of adult Sudanese habitual users of miswak chewing sticks or toothbrushes. Acta Odontol Scand 2000;58:25-30.
al-Otaibi M. The miswak (chewing stick) and oral health. Studies on oral hygiene practices of urban Saudi Arabians. Swed Dent J Suppl 2004;167:2-75.
Darout IA, Skaug N, Albandar JM. Subgingival microbiota levels and their associations with periodontal status at the sampled sites in an adult Sudanese population using miswak or toothbrush regularly. Acta Odontol Scand 2003;61:115-22.
Darout IA, Albandar JM, Skaug N, Ali RW. Salivary microbiota levels in relation to periodontal status, experience of caries and miswak use in Sudanese adults. J Clin Periodontol 2002;29:411-20.
Salehi P, Sh MD. Comparison of the antibacterial effects of persica mouthwash with chlorhexidine on Streptococcus mutans
in orthodontic patients. Daru J Pharm Sci 2006;14:178-82.
Huang SY, Huang JJ, Kang T, Diao DF, Duan YZ. Coating NiTi archwires with diamond-like carbon films: Reducing fluoride-induced corrosion and improving frictional properties. J Mater Sci Mater Med 2013;24:2287-92.
Mirjalili M, Momeni M, Ebrahimi N, Moayed MH. Comparative study on corrosion behaviour of Nitinol and stainless steel orthodontic wires in simulated saliva solution in presence of fluoride ions. Mater Sci Eng C Mater Biol Appl 2013;33:2084-93.
Kassab EJ, Gomes JP. Assessment of nickel titanium and beta titanium corrosion resistance behavior in fluoride and chloride environments. Angle Orthod 2013;83:864-9.
Schiff N, Grosgogeat B, Lissac M, Dalard F. Influence of fluoridated mouthwashes on corrosion resistance of orthodontics wires. Biomaterials 2004;25:4535-42.
Kucukyildirim BO, Eker AA. Surface roughness changes on ß-titanium orthodontic wires after corrosion in various artificial saliva solutions. Mater Testing 2013;55:374-8.
Prashant PS, Nandan H, Gopalakrishnan M. Friction in orthodontics. J Pharm Bioallied Sci 2015;7:S334-8.
Lee TH, Huang TK, Lin SY, Chen LK, Chou MY, Huang HH. Corrosion resistance of different nickel-titanium archwires in acidic fluoride-containing artificial saliva. Angle Orthod 2010;80:547-53.
Castro SM, Ponces MJ, Lopes JD, Vasconcelos M, Pollmann MC. Orthodontic wires and its corrosion – The specific case of stainless steel and beta-titanium. J Dent Sci 2015;10:1-7.
Krishnan V, Krishnan A, Remya R, Ravikumar KK, Nair SA, Shibli SM, et al
. Development and evaluation of two PVD-coated β-titanium orthodontic archwires for fluoride-induced corrosion protection. Acta Biomater 2011;7:1913-27.
Abbassy M, Bakry A. The effect of fluoride on beta-titanium orthodontic wires, surface texture and friction resistance. Int J Dent Oral Sci 2015;2:47-52.
Aghili H, Yassaei S, Eslami F. Evaluation of the effect of three mouthwashes on the mechanical properties and surface morphology of several orthodontic wires: An in vitro
study. Dent Res J (Isfahan) 2017;14:252-9.
Hosseinzadeh Nik T, Hooshmand T, Farazdaghi H, Mehrabi A, Razavi ES. Effect of chlorhexidine-containing prophylactic agent on the surface characterization and frictional resistance between orthodontic brackets and archwires: An in vitro
study. Prog Orthod 2013;14:48.
Alwafe NA, Hammad SM, El-Wassefy NA, Hafez AM. Evaluation of the effect of an experimental herbal versus fluoridated mouthwash on frictional resistance and surface roughness between orthodontic brackets and two types of archwire: In vitro
study. J Dent Mater Technique 2019;8:205-14.
Nalbantgil D, Ulkur F, Kardas G, Culha M. Evaluation of corrosion resistance and surface characteristics of orthodontic wires immersed in different mouthwashes. Biomed Mater Eng 2016;27:539-49.
Sarapan T, Thunyakitpisal P, Chantarawaratit P. Corrosion of metal orthodontic brackets and archwires caused by fluoride-containing products: Cytotoxicity, metal ion release and surface roughness. Orthod Waves 2018;77:79-89.
Omidkhoda M, Poosti M, Sahebnasagh Z, Zebarjad SM, Sahebnasagh Z. Effects of three different mouthwashes on the surface characteristics of nickel-titanium and stainless steel archwires in orthodontics. J Dent Mater Technique 2017;6:19-266.
Danaei SM, Safavi A, Roeinpeikar SM, Oshagh M, Iranpour S, Omidkhoda M. Ion release from orthodontic brackets in 3 mouthwashes: An in-vitro
study. Am J Orthod Dentofacial Orthop 2011;139:730-4.
Dartar Oztan M, Akman AA, Zaimoglu L, Bilgiç S. Corrosion rates of stainless-steel files in different irrigating solutions. Int Endod J 2002;35:655-9.
Brar AS, Singla A, Mahajan V, Jaj HS, Seth V, Negi P. Reliability of organic mouthwashes over inorganic mouthwashes in the assessment of corrosion resistance of NiTi arch wires. J Indian Orthod Soc 2015;49:129. [Full text]
Deriaty T, Nasution I, Yusuf M. Nickel ion release from stainless steel brackets in chlorhexidine and Piper betle Linn mouthwash. Dent J 2018;51:5-9.
Schmalz G, Garhammer P. Biological interactions of dental cast alloys with oral tissues. Dent Mater 2002;18:396-406.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]
[Table 1], [Table 2]