Vol 51 No 1 Jan-Mrt 2018.indd


55

Nickel ion release from stainless steel brackets in chlorhexidine 
and Piper betle Linn mouthwash 

Tanti Deriaty,1 Indra Nasution,2 and Muslim Yusuf3
1 Orthodontist, Medan-Indonesia
2 Department of Mechanical Engineering, Faculty of Engineering ,Universitas Sumatera Utara 
3 Department of Orthodontics, Faculty of Dentistry, Universitas Sumatera Utara
Medan-Indonesia

ABSTRACT

Background: Orthodontist prescribe mouthwash for their patients especially since most of patients do not have a satisfactory oral 
hygiene and have high risk of dental caries. Stainless steel brackets that exposed by mouthwash may have nickel ion release. Corrosion 
and nickel ion release can induced allergic reaction and make more friction during orthodontic treatment. Purpose: This study aimed 
to measure nickel ion release of stainless steel bracket that immersed in chlorhexidine and Piper betle Linn mouthwash. Methods: 
Thirty-six stainless steel bracket immersed in artificial saliva, chlorhexidine, and Piper betle Linn mouthwash. All brackets stored in 
incubator for 1, 3, 5, and 7 weeks. Nickel ion release was measured by Atomic Absorption Spectrophotometry (AAS). Results: The 
results showed a significant differences of nickel ion release in all groups (p<0.05). Conclusion: In conclusion, among the mouthwash, 
chlorohexidine has the highest nickel ion release from stainless steel brackets, followed with Piper betle Linn mouthwash.

Keywords: nickel ion release; stainless steel bracket; chlorhexidine mouthwash; Piper betle Linn. mouthwash 

Correspondence: Tanti Deriaty, Orthodontist. Jl. Sei Ular Baru No.4 Medan Indonesia. E-mail: tantisitepudds@gmail.com.

Research Report

INTRODUCTION

Orthodontic brackets are an important component in 
orthodontic appliances. Brackets should have the correct 
hardness and strength to deliver the exact force from the 
wire to the teeth. They also should have a smooth archwire 
slot to reduce frictional resistance and plaque deposition. 
Orthodontic brackets should be accurately manufactured to 
reflect the prescription type of each bracket. They should 
also have a good biocompatibility and high corrosion 
resistance.1–3

Brackets are usually placed in oral cavity between two 
and three years. During this time, brackets are contaminated 
by substances from the inside and outside mouth. This 
situation can destroy brackets physically and chemically 
then leading to corrosion and ion release. Thus, high 
corrosion resistance metals or alloys are the best choice to 
prevent orthodontic brackets corrosiveness.1,2

Stainless steel bracket is one of metal orthodontic 
bracket. This brackets have some primary advantages such 

as greater strength, lower cost, good modulus of elasticity 
and formability than any other brackets, and have high 
corrosion resistance in the oral cavity.1–4

There are some types of stainless steel brackets, such as 
AISI type 304 L SS, 316 L SS, and 17-4 PH SS. Stainless 
steeel 304 L consist of 18–20% chromium, 8–10% nickel, 
and less than 0.03% manganese, silicon, and carbon. 
Stainless steel 316 L has a higher nickel content than 
304 L, 2–3% molybdenum, and consist of lower carbon 
to improved intergranular corrosion resistance and for 
better welding results. Stainless steel 17-4 PH has similar 
corrosion resistance and higher mechanical property than 
304 type.1–4

Orthodontic corrosion and ion release in oral environment 
have two important concerns. First, when corrosion products 
absorb by body and caused local and systemic toxic effect. 
Nickel ion release was known as the most common allergic 
substance that caused contact dermatitis in women and 
others hypersensitive reaction in 10% of general population. 
Nickel is a strong medium immune reaction that can cause 

Dental Journal
(Majalah Kedokteran Gigi)

2018 March; 51(1): 5–9

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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DOI: 10.20473/j.djmkg.v51.i1.p5–9

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6 Deriaty, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 March; 51(1): 5–9

hypersensitivity reaction, contact dermatitis, gingival 
enlargement, asthma, hypercytotoxicity, and mutagenic. 
Cultured human cells study reported that nickel ion release 
was moderately cytotoxic in cells. Nowadays, there are 
alternative low-nickel and nickel-free alloys to replace 
stainless steel. However, the biocompatibility of low-
nickel alloys have not been accurately evaluated. Second, 
metal corrosion could affect stainless steel physical and 
clinical properties. Metal surface corrosion could increase 
friction of two different type of metal that cause prolonged 
treatment time and uncomfortable tooth movement.5–12

Good oral hygiene is an essential part of a successful 
orthodontic treatment. Orthodontist prescribes mouthwash 
due to most of patients have lack oral hygiene and high 
risk of dental caries. Mouthwashes are effective to prevent 
formability of microbial plaques. Among mouthwashes, 
chlorhexidine has known to be highly effective in 
prevention of dental plaques and reduction Streptococcus 
mutans. However, some studies report that chlorhexidine 
mouthwash could make high ion release due to irrigation 
effect it self.13,14

Recently, the use of herbal mouthwash is increasing. 
Natural products that extract from herbal plants are found 
to be highly efficient to prevent the dental caries/plaque 
found in fixed orthodontic appliances patients undergoing 
orthodontic treatment. One of most common herbal plant 
in Indonesia is Piper betle Linn. This plant has known as 
traditional medication including to prevent bad breath and 
dental caries. Piper betle leaves contains several active 
compounds such as eugenol and its isomers, chavibetol, 
hydroxychavicol, pentatriacontanol, piperol, piperbetol, 
carotenes, and ascorbic acid. Hydroxychavicol has been 
examined as an antimicrobial ingredient, and it shows 
promising results for several applications as an oral care 
agent. Antimicrobial profiles of hydroxychavicol are 
well suited for an active ingredient for oral care products. 
Corrosion behaviour of this plant is still unknown.14–16

This study report measured the levels of nickel 
ion release from stainless steel brackets immersed in 
chlorhexidine and Piper betle Linn mouthwash. These 
results should help orthodontist to prescribe the best choice 
of mouthwash for their patient needs.

MATERIALS AND METHODS

Thirty six brackets (first premolar bracket, stainless 
steel, 0.018-in, Roth prescription, Mini-Gamma SD 
Orthodontic, USA) were used for this study. The brackets 
divided into 12 groups. Each group immersed for 1, 3, 5, and 
7 weeks in different solutions. Group 1-4 is a control group 
that immersed in artificial saliva. Group 5-8 immersed in 
chlorhexidine mouthwash 0.2%. Group 9-12 immersed in 
Piper betle Linn mouthwash 3%. 

Direction of use mouthwash is usually rinse for about one 
minute twice a week, and after having mouthwash, patient 
should not be eating food, drinking, and rinsing their mouth 

to ensure that its components remain present for period 
of time. To calculate the presence of mouthwash active 
ingredient on mouth especially on brackets, we estimated 
that, if an individual  followed this regime, the mouthwash 
components would be present in a patient’s mouth for 6 
hours (twice a week for 24 months is equal 69.000 minutes). 
Therefore, on this study the immersion and incubation time 
of brackets was 49 days (49 days being almost equivalen to 
69.700 minutes).16 Each bracket was placed in individual 
glass tube containing 10 mL of immersion solution and  
incubated at 37° C for 1, 3, 5, and 7 weeks. After incubation, 
the immersion solution was measured with atomic absorption 
spectrophotometer (AAS) (Shimadzu AA-7000).

AAS is spectroanalytical procedure to measuring the 
ion concentration in immersion solution using energy 
absorption from certain wavelength of light (commonly 
190-900 nm). AAS typically include a flame burner to 
atomize the sample (in this research we used a hollow 
cathode lamp as a flame burner), a monochromator and 
a photon detector. Wavelength to measured nickel ion is 
232.10 nm. First, we have to make standard solutions of 
three different concentrations, determine the absorbance 
then make a calibration curve from the values. Fitting 
nickel light source lamp to the lamp housing to measure the 
absorbance then switch on the instrument. Switch on the 
source lamp and set at nickel’s wavelength (232.10 nm). 
Ignite the mixture of these gases. Adjust the gas flow rate 
and pressure, and make the zero adjustment after nebulizing 
the solvent into the flame. The absorbance for the sample 
was measured then determined concentration from the 
previous curve of calibration.17

RESULTS

Results on Table 1 showed nickel ion release mean 
levels in the groups. Therefore, to look the presence of 
different nickel ion release we need to tested data with 
Kruskal-Wallis test in Table 2.

A non-parametric test (Kruskal-Wallis) in Table 1 
showed nickel ion release statistically significant differences 
in artificial saliva among 1, 3, 5 and 7 weeks groups p= 
0.030 (p< 0.05); in chlorhexidine was significantly different 
p= 0.015 (p<0.05); in Piper betle Linn was significantly 
different p=0.015 (p<0.05).

This research not only report based on type solution but 
also based on immersion time (Table 3). Kruskal-Wallis test 
reported nickel ion release statistically significant differences 
in artificial saliva, chlorhexidine, and Piper betle Linn for 1 
week p=0.023 (p<0.05), 3 weeks p=0.020 (p<0.05), 5 weeks 
p=0.017 (p<0.05); and 7 weeks p= 0.015 (p<0.05).

DISCUSSION

Metal corrosion could be happen in the mouth 
environment and released metal ion into saliva. Orthodontist 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i1.p5–9

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7Deriaty, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 March; 51(1): 5–9

commonly recommended mouthwash for their patients to 
decrease the risk of plaque and caries formability. However, 
lack of study reported the effects of various mouthwashes 
on ion release of orthodontic brackets.18

This study reported nickel ion release from stainless steel 
brackets that immersed in artificial saliva, chlorhexidine, 
and Piper betle Linn. mouthwash increased over time. This 
result relevant with Amini’s study that measured chromium 
and nickel concentration in gingival crevicular fluid before 
treatment, 1 month, and 6 months after using orthodontic 
appliance from 24 patients using AAS. The nickel levels 
were increased over time same with this study.19

Among various mouthwash solutions, chlorhexidine 
showed the maximum level of nickel ion released, the next 
highest being in Piper betle Linn mouthwash, and the lowest 
in artificial saliva. This result relevant with Danaei et al. 
study that immersed 160 stainless steel brackets divided 
randomly in four solution groups (chlorhexidine, oral-B 
fluoride, persica mouthwash, and distillated deionized 
water) and incubation time for 45 days at 37° C. Nickel, 

Table 1. Mean levels of the ions released in all groups

Groups 
(solution)

Immersion time 
(weeks)

pn

1 3
0.030*33Artificial saliva

35

37

31

0.015*33Chlorhexidine

35

37

31

Piper betle Linn 0.015*33

35

37

* p<0.05

Table 2. Kruskal-Wallis test of nickel ion released in the artificial saliva, chlorhexidine, and  Piper betle Linn. mouthwash in 1, 3, 
5, 7 weeks 

 Groups

Immersion
time (weeks)

Artificial saliva (control)
(n=3)

χ ± SD
 (ppm)

Chlorhexidine
(n=3)

χ ± SD
 (ppm)

Piper betle Linn.
(n=3)

χ ± SD
(ppm)

0.033 ± 0.006670.185 ± 0.050.0073 ± 0.005771

0.099 ± 0.010000.5463 ± 0.006670.0103 ± 0.005773

0.154 ± 0.020000.9313 ± 0.006670.0113 ± 0.005775

0.203 ± 0.006671.333 ± 0.006670.0133 ± 0.005777

* p<0.05

Table 3. Kruskal-Wallis test in immersion time groups 

Groups 
Immersion time 

(weeks)
pnSolution

3Artificial saliva

0.023*31 Chlorhexidine

Piper betle Linn 3

3Artificial saliva

0.02033 Chlorhexidine *

Piper betle Linn 3

3Artificial saliva

0.0173Chlorhexidine5 *

Piper betle Linn 3

3Artificial saliva

0.01537 Chlorhexidine *

Piper betle Linn 3

* p<0.05

chromium, iron, copper, and manganese ion release were 
measured by inductively coupled plasma spectrometer. The 
highest nickel ion release showed in chlorhexidine solution 
compared with the other mouthwash.20

It reported on a fixed appliance simulator that described 
full upper arch. The samples were measured at 1, 7, 14, 21, 
and 28 days by flame atomic absorption spectrophotometer. 
The highest levels of metal ion release at day 7, and all 
releasing ion is finished within 28 days. This results is not 
relevant with our study.21

Corrosion occurs from either dissolve of metal ions 
into solution or progressive release of a protective layer, 
usually an oxide or a sulphide. The corrosion and metal ion 
release mechanism from stainless steel alloy started from 
dissolved the protective film that consist of chromium oxide 
and chromium hydroxide, and then forms on contact with 
oxygen on the stainless steel’s surface.20

Corrosion made from two simultaneous reactions: 
oxidation and reduction (redox). For example we were using 
iron in a weak acid. Oxidation (anodic) reaction results 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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in dissolution of  the iron as ferrous ions are produced 
(Fe  Fe2++ 2e-). Reduction occurs at  the cathode, with 
hydrogen ions reduced to hydrogen gas (2H++ 2e-  H2). 
This reaction will continue until all of the metal consumed, 
unless the metal can form a protective surface layer 
(passivation), or until the cathodic reactant is consumed 
(exhaustion of  dissolved oxygen in solution).22,23

Corrosion levels of any metal depends on chemical 
reaction of the immersion solution (Figure 1). The formation 
of passive oxide film can delay the corrosion process on the 
orthodontic appliances. However, this protective layer can 
dissolve mechanically and chemically. This passive oxide 
films can slowly dissolve (passivation) without chemical 
or mechanical abrasion only to reform (repassivation) as 
the metal surface is exposed to oxygen from the air or 
the surrounding medium. The passivation reaction could 
accelerated by chloride ions and acidic environment that 
happen because of sodium chloride, acidic carbonated 
drinks intake, and fluoride-containing products, such as 
toothpaste and mouthwash. Some studies reported, the 
corrosion resistance of some metals, especially titanium, 
are decreased in a fluoridated, acidic environment,.22–25

The orthodontic metal alloy risk of corrosion depends on 
the oral environment, which is determined by mechanical 
and chemical factors. Mechanical factors including foods, 
liquids, and tooth brushes abrasion. Chemical factors 
including quantity and quality of saliva, and pH of food 
and beverages. Corrosion will occur continuously in the 
mouth over time.27

Some factor that effect different results betwen studies 
are study design, measuring system, immersion time, and 
immersion solution. Moreover, same products on different 
manufacturers have been shown different results. Surface 
area of the bracket is one of an important factor to determine 
the amount of corrosion and ion release, but calculating 
orthodontic bracket’s comprehensive surface area was on 
our exclusion criteria in this study because of their complex 
shape and geometry. 

The corrosion of brackets could influence the process 
of orthodontic treatment. Nickel ion release can result 
allergic reactions and cytotoxicity. Since the nickel allergic 
reaction is one of our concern, orthodontist should be aware 
that nickel ion release might cause some allergic reaction 
including contact allergy and gingivitis. Contact allergy 
clinically seems at oral soft tissue that contact with brackets. 
In orthodontic patient, severe gingivitis not only related to 
lack of oral hygiene but also to nickel allergic reaction from 
stainless steel brackets. We also need to determine patient 
history of hypersensitivity by anamneses the patient.20

Parameters that affect the corrosion and ion release of 
metals in saliva including immersion time, presence of 
oxygen, pH, and temperature. Metal ion released into the 
oral environment with saliva as the medium. High level of 
chloride contain in saliva, various intake of foods and drinks 
with a low pH could lead to acidic condition that increase 
the amount of corrosion and ion release. Furthermore, the 
characteristics of saliva change according to the patient’s 
health and the time of day can affect the ion release.22–24

In this study, mouthwash was used in a static 
environment. However, in real life, mouthwash were used 
in dynamic environment. Increasing metal ion release 
could happen in dynamic condition not only because of the 
saliva fluidity and pH but also abrasion by tooth brushing 
and mastication mechanism. A large number of metal ion 
release after using an oral functioning simulator apparatus 
to describe the dynamic condition of oral environment.28 In 
this study, we did not use adhesive resin to coverage base 
of brackets so the involved bracket surface was larger than 
clinical conditions.29,30

Average nickel intake a day from foods are 5–100 
mg and 300–500 mg, respectively. Nickel ion intake in 
beverages is commonly under 20 mg per liter. The amount 
of nickel ion released from in this study is lower than daily 
food and water nickel intake. However, patient with nickel 
intolerant reacted even with a small amount of nickel ion 
release.20

This study clearly identifies the risk of corrosion 
and nickel ion release when mouthwashes are used.  
Corrosion could make some clinical problems when 
orthodontic treatment occurs including allergic reaction and 
uncomfortable sliding movements. It also could negatively 
impact the aesthetic result of orthodontic treatment. Patients 
who have metal ion hipersensitivity especially nickel is 
recommended not having mouthwash for a long period of 
time. It seems to be a need for a new type of mouthwash 
containing both anti-caries and corrosion inhibitors which 
could be used without restriction by patients undergoing 
orthodontic therapy. In conclusion, among the mouthwash, 
chlorohexidine has the highest nickel ion release from 
stainless steel brackets, followed with Piper betle Linn 
mouthwash.

Figure 1. Corrosion on orthodontic bracket.26

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i1.p5–9

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9Deriaty, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 March; 51(1): 5–9

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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i1.p5–9

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v51.i1.p5-9