|Year : 2019 | Volume
| Issue : 4 | Page : 209-215
In vivo study on the release of nickel, chromium, and zinc in saliva and serum from patients treated with fixed orthodontic appliances
Dilip Daniel Quadras1, U S Krishna Nayak2, N Suchetha Kumari3, HR Priyadarshini4, Srinivasa Gowda5, Bennete Fernandes6
1 Department of Orthodontics and Dentofacial Orthopedics, Srinivas Institute of Dental Sciences, Mangalore, India
2 Department of Orthodontics, A. B. Shetty Memorial Institute of Dental Sciences, Mangalore, India
3 Department of Biochemistry, K. S. Hegde Medical Academy, Mangalore, India
4 Department of Public Health Dentistry, SEGI University, Malaysia
5 Department of Prosthodontics, AFMC, Pune, MUHS, Nashik, India
6 Department of Periodontics, SEGI University, Malaysia
|Date of Web Publication||24-Jun-2019|
Dr. Dilip Daniel Quadras
Department of Orthodontics and Dentofacial Orthopedics, Srinivas Institute of Dental Sciences, Mangalore - 575 018
Source of Support: None, Conflict of Interest: None
Background: Fixed orthodontic appliances can release metal ions such as nickel, chromium, and zinc into saliva and blood, which can cause contact dermatitis, hypersensitivity, and cytotoxicity.
This study was undertaken to assess the release of nickel, chromium, and zinc in saliva and serum of patients undergoing fixed orthodontic treatment.
Materials and Methods: This in vivo study was conducted on 80 participants with an age range of 15–40 years. Thirty were included as controls and 50 participants were treated with fixed orthodontic appliances. Saliva and blood samples were collected at five different periods, before insertion of fixed orthodontic appliance and at 1 week, 3 months, 1 year, and 1.5 years after insertion of appliance, respectively. The metal ion content in the samples were analyzed by atomic absorption spectrophotometry. Mean levels of nickel, chromium, and zinc in saliva and serum were compared between groups using independent sample t-test and before and after results using paired t-test. P < 0.05 was considered as statistically significant.
Results: At the end of 1.5 years, the mean salivary levels of nickel, chromium, and zinc in controls were 5.02 ppb, 1.27 ppb, and 10.24 ppb, respectively, as compared to 67 ppb, 30.8 ppb, and 164.7 ppb at the end of 1.5 years. This was statistically significant with P < 0.001. A significant increase in the metal ion levels were seen in participants with before and after insertion of appliance (P < 0.001).
Conclusion: Orthodontic appliances do release considerable amounts of metal ions such as nickel, chromium, and zinc in saliva and serum. However, it was within permissible levels and did not reach toxic levels.
Keywords: Chromium, nickel, orthodontic appliances, saliva, zinc
|How to cite this article:|
Quadras DD, Nayak U S, Kumari N S, Priyadarshini H R, Gowda S, Fernandes B. In vivo study on the release of nickel, chromium, and zinc in saliva and serum from patients treated with fixed orthodontic appliances. Dent Res J 2019;16:209-15
|How to cite this URL:|
Quadras DD, Nayak U S, Kumari N S, Priyadarshini H R, Gowda S, Fernandes B. In vivo study on the release of nickel, chromium, and zinc in saliva and serum from patients treated with fixed orthodontic appliances. Dent Res J [serial online] 2019 [cited 2020 Jul 9];16:209-15. Available from: http://www.drjjournal.net/text.asp?2019/16/4/209/261155
| Introduction|| |
Nickel-titanium alloys are commonly used in orthodontics, in manufacturing various components of fixed orthodontic appliances. Metal ions such as nickel, chromium, and zinc can be released from the orthodontic appliances as part of the dissolution and the biomechanical process of alloys. Nickel is a common allergen and powerful sensitizer. With amounts as low as 2.5 ng/mL, nickel has been found to impair the chemotaxis of leukocytes and stimulate neutrophils to become aspherical and move slowly. Ion release can also cause discoloration of the adjacent soft tissues, allergic reactions, or pain.
The patients undergoing orthodontic treatment are exposed to metal alloys in the mouth that can corrode over a period during orthodontic treatment, resulting in the release of ions into oral mucosa and biologic fluids., Corroded orthodontic appliances have shown to cause biologic health hazards including contact dermatitis, hypersensitivity, and cytotoxicity in the past studies.,,,
Orthodontic appliances are made up of austenitic stainless steel, which includes about 8%–12% nickel, 17%–22% chromium, and other trace metals. Thus, metal ions are released from fixed appliances through discharge of electro-galvanic currents, where saliva acts as medium for continuous erosion over a period during orthodontic treatment., Such released metals from fixed orthodontic appliances can result in metal-mediated generation of free radicals which may cause various chemical alterations in DNA bases.
In addition, metals such as chromium and nickel can produce free radical species from molecular oxygen, which in turn produce superoxide anion and highly toxic hydroxyl radical. The generated free radicals also prevent antioxidant enzymes and consume the intracellular glutathione levels, thus intensifying the effects of prooxidants. Fixed orthodontic appliances increase the risk of plaque deposition, periodontal trauma, dental caries, and alteration in endogenously synthesized antioxidants, namely, glutathione-S-transferase and superoxide dismutase in saliva.
The release of metal ions can cause DNA damage in human cells due to oxidative DNA damage (direct interaction) or interference with DNA replication (indirect interaction).,, The mutative action of nickel may derive from its action on inhibiting several enzymes known to restore DNA breaks, promoting mutations, thereby contributing to genetic instability. It seems that multidisciplinary approach toward the problem of the assessment of exposure of the human organism to trace elements may reveal different aspects associated with the application of metals in dentistry.
Although some studies in the past have shown that the level of metals released from orthodontic appliances in saliva or serum was significantly below the average dietary intake and did not reach toxic concentrations, those were short-term studies conducted over few weeks to months. Hence, the present study was carried out to assess nickel, chromium, and zinc levels in saliva and serum samples of patients treated with fixed orthodontic appliances and to determine any significant changes in these concentrations, throughout the treatment.
| Materials and Methods|| |
In this in vivo study The patients were selected from the Department of Orthodontics and Dentofacial Orthopedics, ABSMIDS, Deralakatte, Mangalore. Ethical clearance was obtained from the Institutional Ethical Committee before the commencement of the study (Ref: NU/CEC/PhD-30/2011).
Eighty participants who visited the department for seeking orthodontic treatment and consented to be a part of the study were included for the study after applying the inclusion and exclusion criteria. Healthy participants with permanent dentition within the age range of 15–40 years were included for the study. Participants with genetic syndromes, history of previous orthodontic treatment, allergies to artificial jewelry, under medication, amalgam and metal restorations, expansion and extraoral orthopedic appliance, smokers, and alcoholics were excluded from the study.
The study group included 50 patients who required orthodontic treatment. A detailed case history was obtained from these 50 participants followed by treatment with stainless steel fixed orthodontic appliances (preadjusted edgewise appliance) which consisted of 4–8 bands and 20 bonded brackets (3M Unitek, Monrovia, California). The material was American Iron and Steel Institute type 304 for the orthodontic bands and type 316 for the metal brackets. The archwires used in this study were nickel-titanium alloy and stainless steel (3M Unitek, Monrovia, California). In addition, 30 participants who did not require any orthodontic treatment were included to serve as controls resulting in a total sample size of 80.
Saliva and serum samples were collected from all 80 participants at five intervals, before insertion of the appliance, at 1 week, 3 months, 1 year, and 1.5 years after the insertion of the appliance. Saliva and serum samples were collected in the morning before breakfast. Saliva was collected by the spit method. The patients were asked to rinse their mouth thoroughly with distilled water before the sample collection. The saliva was sampled for 5 min with the mouth closed without stimulation and then transferred to plastic test tubes.
Five milliliters of blood was obtained from the antecubital fossa of the arm and centrifuged at 3000 rpm for 10 min to prepare the serum. Acid-washed plastic containers were used for storage of saliva and serum samples. The samples were kept at −20°C until they were processed. The estimation was carried out by Aǧaoǧlu et al. method. The stored saliva and serum samples were subjected for analysis of nickel, chromium, and zinc in levels.
The spectrophotometric determinations were carried out using an electrothermal atomic absorption spectrophotometer in Nitte University Center for science education and research using Perkin Elmer AAnalyst 800 with graphite surface. Each test was analyzed three times, and the average was used as a result. Before each test distilled water sample was processed to prevent possible contamination. The insoluble precipitate was not included in the analysis because of the problem of particles causing variation in the results.
Data was ere analyzed using SPSS version 22 (IBM Corp, Armonk, NY, USA). The difference in mean levels between study and control groups was assessed using independent sample t-test. The comparisons before and after treatment in the test group were done using paired t-test. P < 0.05 was considered as statistically significant.
| Results|| |
The mean age of the participants was 24.5 ± 1.2 years. Of 50 patients in the study group, 31 were female and 19 were male. Comparison of mean levels of nickel, chromium, and zinc in saliva and serum among study and control groups before the insertion of appliance did not show any significant difference [Table 1].
|Table 1: Comparison of mean metal ion levels in saliva and serum among control and study groups before insertion of appliance |
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[Table 2] shows the mean levels of nickel, chromium, and zinc in saliva and serum of patients with stainless steel appliances at the end of 1.5 years. A significant difference was found in metal ion levels at the end of study between control and study groups. While the nickel, chromium, and zinc levels in saliva of controls was 5.02 ppb, 1.27 ppb, and 10.24 ppb, respectively, and study group was 67 ppb (P = 0.021), 30.8 ppb (P = 0.013), and 164.7 ppb (P < 0.001), respectively. The same was true with the serum levels as well, with the test group having significantly higher levels of metal ions in serum as compared to controls (P < 0.001).
|Table 2: Comparison of mean levels of nickel, chromium, and zinc in saliva and serum among control and study groups at the end of 1.5 years|
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The mean levels of metal ions also showed a steady increase throughout the study in both saliva and serum in patients undergoing orthodontic treatment. In saliva, a slow increase of only 0.10 ppb of nickel, 0.49 ppb of chromium, and 26 ppb of zinc was found during the 1st week which reached a maximum of 67 ppb of nickel, 30.8 ppb of chromium, and 164.5 ppb of zinc at the end of 1.5 years [Table 3].
|Table 3: Mean nickel, chromium, and zinc levels in saliva at different periods in the study group|
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In serum, a slow increase of only 0.38 ppb of nickel, 0.36 ppb of chromium, and 27 ppb of zinc was found during the 1st week which reached a maximum of 81.65 ppb of nickel, 35.6 ppb of chromium, and 597.16 ppb of zinc at the end of 1.5 years. This result was statistically significant with P < 0.001 [Table 4].
|Table 4: Mean nickel, chromium, and zinc levels in serum at different periods in the study group|
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| Discussion|| |
Orthodontic patients are exposed to metal alloys that can corrode in the oral cavity and cause biologic health hazards. The corrosion of metals and ion release has been shown to have additive rather than a linear relationship with time.,, Dental materials within the mouth interact continually with physiologic fluids., The presence of soldered joints increases corrosion susceptibility since they tend to emit electrogalvanic currents with saliva and release metal ions. The use of nickel is of particular concern since it is the most allergenic of all metallic materials. Galvanic current or release of ions could account for many types of dyscrasias such as lichenoid lesions, ulcers, leukoplakia, cancer, and kidney disorder.
Urinary excretion levels of nickel in orthodontic patients have shown significant increase 2 months after treatment. Mobile phone usage has a time-dependent influence on the concentration of nickel in the saliva of patients with orthodontic appliances. Nickel and chromium ions in the scalp hair show slightly elevated levels in patients treated with fixed orthodontic appliances. Listerine causes the highest release of nickel and chromium ions and Listerine Advanced White, Oral B 3D White Luxe, and distilled water were similar in terms of ion release. Oral B caused the lowest release of ions in patients undergoing fixed orthodontic treatment.
Many studies in the past have measured the release of metals in vivo over a short period of 1–3 months. Such a small period is not enough to assess the release of salivary metal ion content of orthodontic appliances. Hence, the present study was designed to cover the entire treatment course of 12–18 months, from appliance placement to the end of treatment. The mean age of patients in the present study was 24.5 ± 1.2 years. Patients were older compared to participants of a study by Aǧaoǧlu et al. in which the mean age of the participants was 19.5 years and Kocadereli et al. in which the mean age was 13 ± 1.2 years.
The most significant and important method for the assessment of nickel release is analysis of saliva since it is the first diluent of the human body and allows long periods of analysis. Thus, the effects of material aging and fatigue on the ion release could be investigated. In the present study, the release of nickel in saliva and serum was initially slow and increased steadily at the end of 1.5 years. However, it was still within the dietary limits and did not reach toxic levels. The salivary nickel concentration has shown a large variation in the past studies.
Nickel concentration in saliva varied from 0.07 to 3.32 μg/mL in a study done by Kocadereli et al., and the release was about 40 μg/mL per day according to Park and Shearer and was not significant when compared to before insertion of the appliance.
A study by Gjerdet et al. showed increase in nickel levels in saliva immediately after placement of orthodontic appliance. In another study by Aǧaoǧlu et al. showed that nickel level in saliva reached the highest level in the 1st month and then decreased during treatment and showed a significant increase in serum nickel level in the 2nd year of treatment. However, a study by Bishara et al. did not find any difference in nickel levels in serum after 4–5 months of treatment.
The variation could be due to differences in dietary habits, geographic location, and method of saliva collection. Furthermore, some studies have been conducted on simulated conditions which will be different from the patient's oral condition. Furthermore, in the present study, a significant difference was found in nickel level in saliva among control and study groups at the end of treatment. A similar result was reported by Amini et al. who found higher levels of nickel in saliva in patients with orthodontic appliances. In a study by Petoumeno et al., nickel levels in saliva increased immediately after placement of orthodontic appliance but decreased after 10 weeks. However, no significant difference was found in saliva among participants with and without appliances in a study by Staffolani et al., Kerosuo et al., and Eliades et al.
Ousehal and Lazrak reported that orthodontic appliances release nickel ions mainly at the start of orthodontic treatment. Nayak et al. reported a statistically significant increase in the nickel after the initial aligning phase, and a net decrease of 1.58 ppb was found after 10–12 months of treatment. This decrease in nickel ion concentration was, however, found to be statistically insignificant. A positive correlation was found in the initial rise in nickel concentration. However, no correlation was found for the change in nickel ion concentration at the end of 10–12 months.
Amini et al. have shown that nickel might increase in patients undergoing treatment with both bracket types – conventional and metal injection molding (MIM) brackets although the rate of increase might be greater in patients undergoing treatment with conventional brackets. Still, ion levels leached from conventional versus MIM brackets might not show a difference after 2 months. Amini et al. showed that induction of stress led to a significant increase in nickel release from orthodontic appliances into saliva. A study by Singh et al. showed that salivary nickel concentrations significantly increased after insertion of fixed orthodontic appliances as compared to baseline levels, with the maximum concentration seen in the 1st week after placement of fixed orthodontic appliances.
Downarowicz et al. have shown that the most biocompatible material used in the production of fixed orthodontic appliances is titanium, and the least biocompatible material is steel, which releases the largest amount of nickel. Metal ions are released from fixed orthodontic appliances only in the first phase of treatment. Orthodontic appliances release nickel ions which induce localized genotoxic effects, but these changes come to normal on the removal of the appliances as reported by Natarajan et al.
In the present study, the release of chromium in saliva and serum was initially fluctuating and increased at the end of 1.5 years. Comparison of mean levels of chromium in saliva and serum of participants in study and control groups showed no significant difference with P > 0.05 before the insertion of appliance and showed the statistically significant difference with P < 0.05 at the end of 1.5 years. However, it was still within the dietary limits and did not reach toxic levels. A study by Eliades et al. found no significant difference between study and control groups in salivary chromium levels.
A study by Aǧaoǧlu et al. showed that chromium in saliva reached the highest level in the 1st month and then decreased to the initial level at the end of treatment and showed statistically significant increase in chromium levels in serum in the 2nd year groups. Kerosuo et al. found no significant increase in chromium levels in saliva before and after 1 month of orthodontic treatment. Whereas, a study by Kocadereli et al. found a significant increase in salivary chromium level during the first 2 months of treatment.
Nayak et al. reported a statistically significant increase in chromium ion concentration after the initial aligning phase and a net increase of 17.92 ppb was found at the end of 10–12 months, which were statistically significant. A positive correlation was found for the increase in chromium ion concentration after the initial alignment and at the end of 10–12 months.
Amini et al. have shown that using MIM brackets might reduce salivary chromium for a trivial but generalizable amount. Still, ion levels leached from conventional versus MIM brackets might not show a difference after 2 months. Chromium concentrations significantly increased after 1 week of insertion of fixed orthodontic appliances have been reported by Singh et al.
Downarowicz et al. have shown that chromium released from fixed orthodontic appliances only in the first phase of treatment. Chromium alloys released from orthodontic appliances have known to cause localized genotoxic effects, but these changes come to normal on the removal of the appliances as reported by Natarajan et al. A study by Matos de Souza et al. found the highest chromium levels in saliva immediately after placement of appliance. A study by Amini et al. showed an increase in salivary chromium levels in patients as compared to the controls. However, this difference was not statistically significant.
In the present study, the levels of zinc in saliva and serum also showed a steep increase in its concentration level at the end of 1.5 years. Comparison of mean levels of zinc in the saliva of participants in study and control groups showed no significant difference with P > 0.05 before the insertion of appliances and showed the statistically significant difference with P < 0.05 at the end of 1.5 years. However, it was still within the dietary limits and did not reach toxic levels. A study by Mikulewicz et al. showed higher concentration of zinc in artificial saliva in which bands and brackets were incubated. However, this study was done outside the oral cavity, and hence, the result cannot be directly compared to the present in vivo study. Since no studies have been conducted to assess the zinc levels in saliva and serum of orthodontic patients, the results of the present study cannot be compared.
In most of the studies, metals released from orthodontic appliances in saliva and serum were significantly below the average dietary intake and did not reach toxic levels. There is a high variation in the levels of metal ions in saliva among patients undergoing orthodontic treatment shown by studies in the past. These variations can be attributed to the difference in techniques of preparation of samples as well as different analytical methods. Furthermore, most of the studies conducted are in vitro which do not exactly reflect the oral environment.
Other factors which change the levels of metals in the in vivo studies could be related with eating, drinking, or toothbrushing. The WHO guideline values for drinking water currently accept the concentration for nickel at 70 μg/mL and chromium at 50 μg/mL which are higher than saliva of patients as found in many studies. The normal range of metal ions in the body is 300–600 μg for nickel and 50–200 μg for chromium which is higher than saliva and serum of patients as found in many studies. A similar result has been found in the present study.
| Conclusion|| |
Orthodontic appliances used to treat patients release considerable amounts of nickel, chromium, and zinc into saliva and serum during different periods of treatment as analyzed in our study. However, the levels were well below the average dietary intake and did not reach toxic levels.
Financial support and sponsorship
The authors are thankful to the Indian Council of Medical Research, Government of India, for financial support. (Sanction No: 5/4/2-12-2009-NCD-II).
Financial support and sponsorship
The authors of this manuscript declare that they have no conflicts of interest, real or perceived, financial or nonfinancial in this article.
Conflicts of interest
There are no conflicts of interest.
| References|| |
Ousehal L, Lazrak L. Change in nickel levels in the saliva of patients with fixed orthodontic appliances. Int Orthod 2012;10:190-7.
Jamshidi S, Rahmati Kamel M, Mirzaie M, Sarrafan A, Khafri S, Parsian H, et al.
Evaluation of scalp hair nickel and chromium level changes in patients with fixed orthodontic appliance: A one-year follow-up study. Acta Odontol Scand 2018;76:1-5.
Nayak RS, Khanna B, Pasha A, Vinay K, Narayan A, Chaitra K, et al.
Evaluation of nickel and chromium ion release during fixed orthodontic treatment using inductively coupled plasma-mass spectrometer: An in vivo
study. J Int Oral Health 2015;7:14-20.
Mirhashemi A, Jahangiri S, Kharrazifard M. Release of nickel and chromium ions from orthodontic wires following the use of teeth whitening mouthwashes. Prog Orthod 2018;19:4.
Summer B, Fink U, Zeller R, Rueff F, Maier S, Roider G, et al.
Patch test reactivity to a cobalt-chromium-molybdenum alloy and stainless steel in metal-allergic patients in correlation to the metal ion release. Contact Dermatitis 2007;57:35-9.
Burrows D. Hypersensitivity to mercury, nickel and chromium in relation to dental materials. Int Dent J 1986;36:30-4.
Grimsdottir MR, Gjerdet NR, Hensten-Pettersen A. Composition and in vitro
corrosion of orthodontic appliances. Am J Orthod Dentofacial Orthop 1992;101:525-32.
Barrett RD, Bishara SE, Quinn JK. Biodegradation of orthodontic appliances. Part I. Biodegradation of nickel and chromium in vitro
. Am J Orthod Dentofacial Orthop 1993;103:8-14.
Lü X, Bao X, Huang Y, Qu Y, Lu H, Lu Z, et al.
Mechanisms of cytotoxicity of nickel ions based on gene expression profiles. Biomaterials 2009;30:141-8.
David A, Lobner D.In vitro
cytotoxicity of orthodontic archwires in cortical cell cultures. Eur J Orthod 2004;26:421-6.
Harris EF, Newman SM, Nicholson JA. Nitinol arch wire in a simulated oral environment: Changes in mechanical properties. Am J Orthod Dentofacial Orthop 1988;93:508-13.
Vandekerckhove R, Temmerman E, Verbeeck R. Electrochemical research on the corrosion of orthodontic nickel-titanium wires. Material Sci Forum 1998;289:1289-98.
Dayan AD, Paine AJ. Mechanisms of chromium toxicity, carcinogenicity and allergenicity: Review of the literature from 1985 to 2000. Hum Exp Toxicol 2001;20:439-51.
Das KK. A comprehensive review on nickel (II) and chromium VI toxicities- possible antioxidant (Allium sativum
linn) defenses. Al Ameen J Med Sci 2009;2:43-50.
Stohs SJ, Bagchi D. Oxidative mechanisms in the toxicity of metal ions. Free Radic Biol Med 1995;18:321-36.
Miricesco D, Greaby M, Totan A, Didilescu A, Rădulescu R. The antioxidant potential of saliva: Clinical significance in oral diseases. Ther Pharmacol Clin Toxicol 2011;2:139-43.
Hartwig A. Current aspects in metal genotoxicity. Biometals 1995;8:3-11.
Fernández-Miñano E, Ortiz C, Vicente A, Calvo JL, Ortiz AJ. Metallic ion content and damage to the DNA in oral mucosa cells of children with fixed orthodontic appliances. Biometals 2011;24:935.
Faccioni F, Franceschetti P, Cerpelloni M, Fracasso ME.In vivo
study on metal release from fixed orthodontic appliances and DNA damage in oral mucosa cells. Am J Orthod Dentofacial Orthop 2003;124:687-93.
Eliades T, Trapalis C, Eliades G, Katsavrias E. Salivary metal levels of orthodontic patients: A novel methodological and analytical approach. Eur J Orthod 2003;25:103-6.
Hwang CJ, Shin JS, Cha JY. Metal release from simulated fixed orthodontic appliances. Am J Orthod Dentofacial Orthop 2001;120:383-91.
Aǧaoǧlu G, Arun T, Izgi B, Yarat A. Nickel and chromium levels in the saliva and serum of patients with fixed orthodontic appliances. Angle Orthod 2001;71:375-9.
Fors R, Persson M. Nickel in dental plaque and saliva in patients with and without orthodontic appliances. Eur J Orthod 2006;28:292-7.
Chaturvedi TP, Bansal R. Biocompatibility of dental implant materials: An overview. J Indian Dent Assoc 2008;2:335-7.
Chaturvedi TP, Upadhayay SN. An overview of orthodontic material degradation in oral cavity. Indian J Dent Res 2010;21:275-84.
] [Full text]
Chaturvedi TP. An overview of the corrosion aspect of dental implants (titanium and its alloys). Indian J Dent Res 2009;20:91-8.
] [Full text]
Menezes LM, Quintão CA, Bolognese AM. Urinary excretion levels of nickel in orthodontic patients. Am J Orthod Dentofacial Orthop 2007;131:635-8.
Saghiri MA, Orangi J, Asatourian A, Mehriar P, Sheibani N. Effect of mobile phone use on metal ion release from fixed orthodontic appliances. Am J Orthod Dentofacial Orthop 2015;147:719-24.
Kocadereli L, Ataç PA, Kale PS, Ozer D. Salivary nickel and chromium in patients with fixed orthodontic appliances. Angle Orthod 2000;70:431-4.
Matos de Souza R, Macedo de Menezes L. Nickel, chromium and iron levels in the saliva of patients with simulated fixed orthodontic appliances. Angle Orthod 2008;78:345-50.
Park HY, Shearer TR.In vitro
release of nickel and chromium from simulated orthodontic appliances. Am J Orthod 1983;84:156-9.
Gjerdet NR, Erichsen ES, Remlo HE, Evjen G. Nickel and iron in saliva of patients with fixed orthodontic appliances. Acta Odontol Scand 1991;49:73-8.
Bishara SE, Barrett RD, Selim MI. Biodegradation of orthodontic appliances. Part II. Changes in the blood level of nickel. Am J Orthod Dentofacial Orthop 1993;103:115-9.
Amini F, Jafari A, Amini P, Sepasi S. Metal ion release from fixed orthodontic appliances – An in vivo
study. Eur J Orthod 2012;34:126-30.
Petoumeno E, Kislyuk M, Hoederath H, Keilig L, Bourauel C, Jäger A, et al.
Corrosion susceptibility and nickel release of nickel titanium wires during clinical application. J Orofac Orthop 2008;69:411-23.
Staffolani N, Damiani F, Lilli C, Guerra M, Staffolani NJ, Belcastro S, et al.
Ion release from orthodontic appliances. J Dent 1999;27:449-54.
Kerosuo H, Moe G, Hensten-Pettersen A. Salivary nickel and chromium in subjects with different types of fixed orthodontic appliances. Am J Orthod Dentofacial Orthop 1997;111:595-8.
Eliades T, Pratsinis H, Kletsas D, Eliades G, Makou M. Characterization and cytotoxicity of ions released from stainless steel and nickel-titanium orthodontic alloys. Am J Orthod Dentofacial Orthop 2004;125:24-9.
Amini F, Harandi S, Mollaei M, Rakhshan V. Effects of fixed orthodontic treatment using conventional versus metal-injection molding brackets on salivary nickel and chromium levels: A double-blind randomized clinical trial. Eur J Orthod 2015;37:522-30.
Amini F, Rahimi H, Morad G, Mollaei M. The effect of stress on salivary metal ion content in orthodontic patients. Biol Trace Elem Res 2013;155:339-43.
Singh DP, Sehgal V, Pradhan KL, Chandna A, Gupta R. Estimation of nickel and chromium in saliva of patients with fixed orthodontic appliances. World J Orthod 2008;9:196-202.
Downarowicz P, Mikulewicz M. Trace metal ions release from fixed orthodontic appliances and DNA damage in oral mucosa cells by in vivo
studies: A literature review. Adv Clin Exp Med 2017;26:1155-62.
Natarajan M, Padmanabhan S, Chitharanjan A, Narasimhan M. Evaluation of the genotoxic effects of fixed appliances on oral mucosal cells and the relationship to nickel and chromium concentrations: An in vivo
study. Am J Orthod Dentofacial Orthop 2011;140:383-8.
Mikulewicz M, Chojnacka K, Woźniak B, Downarowicz P. Release of metal ions from orthodontic appliances: An in vitro
study. Biol Trace Elem Res 2012;146:272-80.
[Table 1], [Table 2], [Table 3], [Table 4]