Electric Field and SAR Distribution in the Vicinity of Orthodontic Brace Exposed to the Cell Phone Radiation

Jovanovic DB, Krasic DD, Stankovic VB, Cvetkovic, NN, Vuckovic DD. Electric Field and SAR Distribution in the Vicinity of Orthodontic Brace Exposed to the Cell Phone Radiation. Applied Computational Electromagnetics Society Journal 34(12):1904-1914. Dec 2019.


The aim of this study is to investigate the impact of orthodontic brace on the electric field distribution and amount of the absorbed energy from the cell phone within the teeth. A comparative analysis of the models (child and adult) with and without brace has been carried out due to different morphological and tissue characteristics of child’s and adult’s head. The 3D realistic models of the child’s and adult’s head, with the jaw having the orthodontic brace, have been designed. The shapes and features of the child and adult head model, as well as the distance between the electromagnetic source and the exposed object, have an important role in the evaluation of the Specific Absorption Rate (SAR). The applied procedure is based on the numerical solution of the electromagnetic waves propagation equations. The numerical analysis has been performed at the frequency of 3G (0.9GHz). The obtained results are represented within the teeth positioned on the side of the electromagnetic radiation source. Based on the obtained results, one can conclude that the presence of orthodontic brace affects the increase of electric field and SAR within the teeth.
“According to previous studies, one can find that the metal objects can significantly increase the amount of absorbed energy. The authors in [1] have found that the SAR values can be several times greater in the presence of metal object. The effect of electromagnetic radiation from mobile phone on nickel release from orthodontic brackets has been taken into consideration in study [2]. It is found that the concentration of nickel in the artificial saliva in the exposure group was significantly higher than that of the control group. The level of the nickel released in this investigation was far below the toxic level but maybe enough that can lead to allergic reaction in humans. One of the previously studies [3] reported the involuntary movements of the subjects, which had gold (metal) alloy dental inlay, caused by electromagnetic waves.”
“It is evident that the value of the electric field is significantly greater in the presence of an orthodontic brace for both models. Based on the results shown in Figs. 6-8, as well as the results given in Table 3, the overall conclusion is that the presence of an orthodontic brace increases the electric field strength within the teeth.

Also it is noticeable that the electric field strength in the case of a child is higher comparing to the adult case.”
“Since the referent value for the electric field, prescribed by adequate standards at 0.9 GHz, is 41 V/m, comparing the results obtained by numerical calculation with values prescribed by safety standards, it is evident that obtained results exceed the referent levels inside all teeth in both models (with and without the orthodontic brace). However, it should be kept in mind that in the case of model with orthodontic brace the values are many times greater than the allowable values.”
“Regarding the obtained results for SAR within the teeth, in the presence of an orthodontic brace, a significant increase in the amount of absorbed energy can be observed. The maximum of SAR1g occurs in the tooth No. 6 in the case of a child (2.46 W/kg). This value is about 65% higher comparing to the adult with orthodontic brace and 45% higher comparing to the results obtained for a child without orthodontic brace. In this tooth and tooth No. 5, the SAR1g overcomes the safety values but only in the case of child in the presence of the orthodontic brace. The amount of absorbed energy inside the other teeth satisfies basic restriction. However, the increase in the amount of absorbed energy in the presence of an orthodontic brace is not negligible.”
“Based on the obtained results, one can conclude that the presence of orthodontic brace causes increase of electric field and SAR within the teeth. In some cases, those values overcome referent limits for electric field strength, i.e., safety limits for SAR values.”
“Because of the mentioned before and the fact that each standard contains specific safety limits of exposure to electromagnetic fields but they have been developed based on the research for adults, it should be established if they are sufficiently valid also in case of children.

The future researches should be focused on the impact of orthodontic brace on the electric field strength and amount of absorbed energy at the frequency of LTE-4G, and the latest generation of mobile networks – 5G.”

Note: The FCC radio frequency radiation exposure limit (i.e., SAR1g) for cell phones is 1.6 W/kg.






August 3, 2015


A new peer-reviewed study found that cell phone use significantly
increased nickel concentration in the saliva of 50 adult patients who wore dental braces
(i.e., fixed orthodontic appliances) as compared to when they did not use their
cell phones for a week. Moreover, patients who spoke more on their cell phone had
a greater increase in salivary nickel concentration. 

The “adverse effect of
radiation on the release of nickel was more prominent in women” because they
spoke more on their cell phones. The females averaged 53 minutes during the week
they used their cell phones whereas the males averaged 23 minutes.
Nickel is a known toxic and carcinogenic metal. It is also a
common cause of metal-induced contact allergic dermatitis. Nickel-containing
alloys are often used in orthodontics for metallic brackets, arch wires, and bands.
Previous research either found no increase in salivary nickel
concentration after a fixed orthodontic appliance was inserted or a significant
increase that tapered off within three weeks after insertion.  The patients in the current study had
orthodontic appliances for 2-4 months before they participated to control for this potential confounding effect of time.
The Federal Communications Commission (FCC) requires all cell phone models be tested for their Specific Absorption Rate (SAR), a
measure of the maximum amount of microwave radiation absorbed by the head and the body. SAR is measured in a laboratory using an artificial model of a large
adult male with different fluids to simulate human tissue. 
The SAR testing
procedure, adopted in 1996, was criticized by the Government Accountability Office in 2012 because it does not simulate today’s typical user
or the way cell phones are typically used. The artificial head does not contain any metal
(e.g., dental fillings, dental braces, metallic earrings or eyeglass frames) which
could increase the radiation absorption beyond that measured in the
laboratory.
 The artificial body test makes the unrealistic assumption that  consumers will carry their cell phones in manufacturer-approved
holders that keeps the phones a minimum distance away from their bodies. 
Today many children are cell phone users.  The young child’s brain absorbs twice the
radiation as the adult’s brain. The SAR testing procedure does not take this
into account.  
Although the current study
was conducted on young adults who had fixed orthodontic appliances, the results
should have relevance for children who are more likely to be fitted for dental braces
than adults.
The paper did not describe the specific types of fixed orthodontic appliances the patients had.

The abstract for the study and excerpts from the paper appear below.

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 Jun;147(6):719-24. doi:
10.1016/j.ajodo.2015.01.023.
INTRODUCTION:  The aim
of this study was to evaluate the effect of exposure to radiofrequency
electromagnetic fields emitted by mobile phones on the level of nickel in
saliva.
METHODS:  Fifty
healthy patients with fixed orthodontic appliances were asked not to use their
cell phones for a week, and their saliva samples were taken at the end of the
week (control group). The patients recorded their time of mobile phone usage
during the next week and returned for a second saliva collection (experimental
group). Samples at both times were taken between 8:00 and 10:00 pm, and the
nickel levels were measured. Two-tailed paired-samples t test, linear
regression, independent t test, and 1-way analysis of variance were used for
data analysis.
RESULTS:  The 2-tailed
paired-samples t test showed significant differences between the levels of
nickel in the control and experimental groups (t [49] = 9.967; P <0.001).
The linear regression test showed a significant relationship between mobile
phone usage time and the nickel release (F [1, 48] = 60.263; P <0.001; R(2)
= 0.577).
CONCLUSIONS:  Mobile
phone usage has a time-dependent influence on the concentration of nickel in
the saliva of patients with orthodontic appliances.
Highlights
•  Radiofrequencies from mobile phones and nickel concentrations in saliva were examined.
•  Mobile phone radiation is positively correlated with nickel concentration in saliva.
•  Nickel concentrations in saliva were different in men and women.
An integral part of modern telecommunication is the mobile
phone, which may have negative effects on different organs and cells. These
negative impacts culminate from radiofrequency electromagnetic radiation (RFER)
emitted from mobile phones. From 1990 to 2011, worldwide mobile phone
subscriptions grew from 12.4 million to over 5.6 billion, and the global
pandemic usage of mobile phones was about 70% as of 2011.  Insufficient understanding of the potential
adverse health effects of mobile phones have raised concerns among health care
professionals.
According to the proximity of mobile phones to the oral
cavity during the conversation period and the metallic orthodontic appliances
in the mouth, there might be a serious risk in exposure of these appliances to
the mobile phone radiation. Archwires, headgear, bands, and brackets used in
orthodontics mainly consist of nickel. The harmful effects of nickel have been
systematically investigated at the levels of the cells, tissues, organs, and
organisms.  According to the
International Agency for Research on Cancer, nickel compounds are classified as
carcinogenic to humans, but it is still unclear which forms of nickel pose the
greatest risk. Nickel complexes in the form of arsenides and sulphides are
carcinogenic, allergenic, and mutating substances even at nontoxic
concentrations. Nickel might induce DNA alterations mainly through basic damage
and DNA-strand scission in G12 cultured cells. Empirically, a biologic limit of
30 μg per gram has been proposed for nickel in the urine of workers exposed to
soluble nickel compounds at the end of their shifts.
Nickel is a common metal that can cause allergic contact
dermatitis more than all other metals. Previous studies have indicated that
approximately 10% of the population is sensitive to nickel, and this
sensitivity is more commonly seen in female patients.
The anatomic location of the parotid gland (at the anterior
border of the external ear and between the mandibular ramus and the
sternocleidomastoid muscle, 4- to 10-mm deep under the skin surface) makes it a
conceivable candidate to be influenced by exposure to RFER on the side of the
head where the mobile phone is held. Some researchers, in both human and animal
studies, have confirmed that mobile phones cause significant increases in
salivary oxidative stress, salivary flow, total proteins, and albumin, whereas
amylase activity was decreased. In a nationwide case-control study, Sadetzki et
al examined the correlation between parotid gland tumors and mobile phone usage
and indicated a positive dose-dependent response trend. Thus, the RFER emitted
from mobile phones may influence the amount of nickel released from the fixed
orthodontic appliances.
… the aim of this study was to test the hypothesis that
exposure to RFER emitted by mobile phones can affect the level of nickel in
saliva. In addition, the effect of different times of exposure to the RFER was
evaluated on the concentration of nickel in saliva.
Fifty healthy patients (25 men, 25 women; average age, 25.2
years; range, 23-26 years) who had fixed orthodontic appliances were selected
for the study. Candidates needed placement of full orthodontic appliances for
at least 2 months and no more than 4 months to satisfy the inclusion criterion.
During the regular checkups, the patients were asked not to
use their cell phones for 1 week, and saliva samples were taken from them at
the end of the week (this was considered the control group). For the next
visit, a chronometer was given to the patients to calculate how many minutes
they used their cell phone during the second week of the experiment. At the end
of the second week, saliva samples were again collected, and the sexes, ages,
and cell phone usage times were also recorded; this was considered the
experimental group. The saliva samples were sent to the laboratory for further
analysis.
The main outcome of the study was a significantly higher
concentration of nickel ions in patients’ saliva after using their mobile
phones compared with the control group. The mobile phones used in this study
had emissions of radiation in the normal range of 800 to 2200 MHz, as mentioned
above.
The concentrations of salivary calcium, magnesium, and
phosphate were lower in the mobile user group. 
Our results showed that the concentrations of nickel ions after using a
cell phone for 1 week were significantly higher than the concentrations in the
control group. This might be attributed to the greater flow rate and the lower
concentration of the components in saliva, which in turn result in more nickel
released from fixed orthodontic appliances into the saliva.
The linear regression test showed a positive significant
increase in nickel concentration with mobile phone usage time. In other words,
the longer the exposure to the RFEF emitted by a mobile phone, the greater the
concentration of nickel in saliva.
According to results of our study, mobile phone radiation
might cause DNA damage indirectly by influencing the release of nickel from
fixed orthodontic appliances. Thus, the necessity of studying the effects of
this radiation on metal ions released from fixed orthodontic appliances in
adjacent tissues seems to be undeniable.
Conclusions
According to the outcomes of this study, it can be concluded
that mobile phone radiation, regardless of the type of phone, can influence the
concentration of nickel in saliva in a time-dependent manner. In addition, this
adverse effect of radiation on the release of nickel was more prominent in
women because of longer usage times. Future large-scale studies, which should
include more parameters such as the effects on the parotid glands or the saliva
flow rate, are needed.

https://www.saferemr.com/2015/08/cellphone-use-may-be-harmful-for-people.html