1http://dx.doi.org/10.20396/bjos.v18i0.8657258

Volume 18
2019
e191605

Original Article

1 Department of Orthodontics, 
Araras Dental School, Uniararas, 
Araras, SP, Brazil.

2 Department of Restorative 
Dentistry, Dental Materials 
Division, Piracicaba Dental School, 
UNICAMP – Universidade Estadual 
de Campinas, Piracicaba, SP, Brazil.

Corresponding author:  
Heloisa Cristina Valdrighi 
Av. Dr. Maximiliano Baruto, 500 - 
Jardim Universitário.  
Araras, SP – Brazil. 
13607-339  
+55 19 35431423 
e-mail: heloisavaldrighi@gmail.com 

https://orcid.org/0000-0001-7567-1990

Received: March 29, 2019 

Accepted: August 23, 2019

Evaluation of friction on  
self-ligating and 
conventional brackets 
associated with different 
types of archwires submitted 
to sliding mechanics
William Carlos Silva Barbosa1, Américo Bortolazzo 
Correr2, Diego Patrik Alves Carneiro1, Mário 
Vedovello Filho1, Ana Paula Terossi de Godoi1, 
Heloísa Cristina Valdrighi1,*

Aim: The aim of this study was to verify the frictional force 
during sliding mechanics in orthodontic tooth movement, using 
conventional metal brackets of the active and passive self-
ligating types with stainless steel and copper nickel titanium 
archwires. Methods: This experimental in vitro study was 
conducted with conventional metal (Morelli, Sorocaba, SP, Brazil) 
brackets, active self-ligated (SLI Morelli, Sorocaba, SP, Brazil) 
and passive self-ligated (SLP Morelli, Sorocaba, SP, Brazil), with 
slot 0.022 x 0.028 inches and Roth prescription.  The brackets 
were tested with rectangular section 0.019 x 0.025 inch copper 
nickel titanium and stainless steel archwires. For each type of 
bracket, 10 sets of plate/bracket/archwire segment (n=10) were 
fabricated. Non-parametric Kruskal Wallis and Dunn tests were 
used for comparison between types of brackets and Wilcoxon 
tests for comparison between types of archwires. Results: 
The results showed that the frictional force values were higher 
with copper nickel titanium than with stainless steel archwires 
(p<0.05). When copper nickel titanium archwires were used, the 
active self-ligating brackets showed higher frictional force values 
than the other types, followed by the conventional brackets.  
Lower frictional force values were observed with passive self-
ligating brackets. For stainless steel archwires, no difference 
was observed between conventional and active self-ligating 
brackets, the passive self-ligating type presented lower frictional 
force values than the others. Conclusion: It was concluded that 
the higher frictional force was observed when active self-ligating 
brackets were associated with copper nickel titanium archwires.  
Lower frictional force was verified between passive self-ligating 
brackets combined with stainless steel archwires.

Keywords: Orthodontic brackets. Friction. Orthodontic appliance 
design.

https://orcid.org/0000-0001-7567-1990


2

Barbosa et al.

Introduction

The frictional resistance present when performing orthodontic sliding mechanics 
results from interactions between the bracket, arch and method of ligation1-9.

A high frictional coefficient may reduce the force used for orthodontic movement 
by half, diminishing the speed of tooth movement and making it difficult to control 
anchorage. The frictional force should be as low as possible with the goal of achieving 
greater mechanical efficiency; that is, the force applied must be sufficient to break the 
static friction and enable tooth movement2,6,9,10-13. 

The frictional force may vary according to the materials used, and whether the envi-
ronment is wet or dry, type of brackets, archwires and ligations. Self-ligating brack-
ets may be divided into active and passive types; the active types have a spring clip 
that invades the bracket slot putting pressure on the archwire, while in the passive 
system, the clip does not invade the slot, it only covers the slot without putting pres-
sure on the archwire1-5,7,10,12,14-19. 

Among the various wires used for making orthodontic arches, stainless steel wires 
are outstanding as they have a polished surface14,20. However, the technological evo-
lution has led to new archwires being used, among them the nickel titanium type with 
the addition of copper (CuNiTi)17,21. The incorporation of copper has resulted in these 
archwires having more defined thermoactive properties than the superelastic NiTi 
archwires, therefore, they exert more homogeneous forces throughout the arch, pro-
viding faster, more effective movement, in an optimal system of forces, with greater 
control of tooth movement; they may be used in different orthodontic treatment pro-
tocols, as they achieve more biologically compatible results by releasing more physi-
ological force and shortening the time of treatment2,4,10,21-23.

The frictional forces between conventional and (passive and active) self-ligating 
brackets, associated with archwires that have different section and compositions 
have been studied2,6,12,24. However, no reports were found of studies comparing the 
frictional force between active and passive self-ligating brackets with rectangular 
0.019 x 0.025 inch sections of copper nickel titanium and stainless steel, in a wet 
environment at a temperature of 36.50 C.  

The hypothesis under study was that metal self-ligating brackets would produce lower 
frictional force than that of conventional metal brackets; and copper nickel titanium 
archwires would produce higher frictional forces than those of stainless steel archwires.

Thus the aim of this study was to verify the frictional force during sliding mechanics 
in orthodontic tooth movement, using conventional metal brackets of the active and 
passive self-ligating types in combination with stainless steel and copper nickel tita-
nium archwires.

Materials and Methods:
This experimental in vitro study was conducted with 30 sets of plate/bracket/archwire 
segments that were divided into three Groups according to the brackets used, i.e., 



3

Barbosa et al.

conventional metal (Ref.   10.10.901, Morelli, Sorocaba, SP, Brazil), active self-ligat-
ing metal (Ref. 10.14.900, SLI/ Morelli, Sorocaba, SP, Brazil) and passive self-ligating 
metal brackets (Ref. 10.13.900, SLP/ Morelli, Sorocaba, SP, Brazil). For each bracket 
type, 10 sets of plate/bracket/segment (n=10) were fabricated6,16,25. The brackets 
were tested with rectangular section 0.019 x 0.025 inch copper nickel titanium (Ref. 
50.62.154, Morelli, Sorocaba, SP, Brazil), and stainless steel archwires (Ref. 50.62.004, 
Morelli, Sorocaba, SP, Brazil)2,3,11.

The test specimens were made up of a rectangular acrylic plate3,5,10,14,25, measuring 
8.5 cm long, 4 cm wide and 0.5 cm thick with metal brackets (conventional), slot 
0.022 x 0.028 inches, from the maxillary right 2nd premolar to the maxillary right cen-
tral incisor5,14, combined with a segment of rectangular section 0.019 x 0.025 inches 
of copper nickel titanium and stainless steel (Morelli, Sorocaba, SP, Brazil)3,5,25, as 
shown in Figure 1.

1 cm

1 cm

2 cm

2 cm2 cm

5 cm

2 cm

Figure. 1 - Schematic drawing of the acrylic plate (8.5 cm long, 4 cm wide and 0.5 cm thick). Metal 
brackets were positioned 0.5 mm distant from each other. The archwire was fixed on the brackets to 
frictional force evaluation. 

The position of each bracket was demarcated on the plate and abraded with a spheri-
cal bur at low speed, cleaned with gauze imbibed in 70% alcohol, and dried with absor-
bent paper towels to prevent the presence of substances or dirt that could compromise 
the results obtained, thereby increasing the relationship of brackets and preventing 



4

Barbosa et al.

these from debonding from the plate during the tests11,13. The brackets were aligned 
in parallel on in the most central region of the plate, so that the center of each bracket 
remained at a distance of 2 cm from the lateral borders and at a distance of 0.5 cm 
from each other.  The brackets localized in the upper and lower extremities remained 
at a distance of 2 cm from the top and bottom edges of the acrylic plate3,5,14,25. 

After this, the brackets were fixed with cyanoacrylate adhesive (Super Bonder, Loc-
tite Henkel, SP, Brazil), before a device was bonded on a 0.021 x 0.025 inch thick 
“U”-shaped11 stainless steel archwire (Ref. 55.03.015, Morelli, Sorocaba, SP, Brazil), 
which was fitted into the channels of the brackets, and its extremities were fixed in 
holes made in the plate at a distance of 1 cm from its top and bottom edges. This 
was done to obtain the maximum level of standardization among the groups, to 
prevent any poorly positioned bracket from affecting the reliability of the results11,14.  
After the brackets were fixed, the rectangular archwire segments of copper nickel 
titanium and stainless steel, measuring 0.019 x 0.025 inches and 20 cm long 
were positioned3,10,23,24. 

The arch segments of 0.019 x 0.025 inches were fixed to the conventional metal 
brackets by conventional elastomeric ligatures (Ref. 60.06.101, Morelli, Sorocaba, SP, 
Brazil), in accordance with previously used methodology5,14,25.

To simulate the conditions of the oral cavity, the tests were performed in a wet 
environment. The test specimens remained in a glass receptacle submersed in 12 
liters of water at a temperature of 36.5 oC, because activation of the copper nickel 
titanium archwire occurs at 35 oC. The temperature of the water was controlled by 
two mercury thermometers2,14,15,20. 

Assay to determine the frictional force

To evaluate the frictional force, a Universal Test Machine (Instron model 4411, 
Buckinghamshire, England) with a 50 N load cell and 5 mm/min crosshead speed 
was used25. The archwire was moved 5 mm on the brackets and the friction evalu-
ated. The results corresponding to the static frictional force were transmitted to the 
Bluehill 2.0 Materials Testing Software (Instron, Norwood, MA 02062- 2643, U.S.A.), 
coupled to the testing machine. The tests were repeated five times in each plate/
bracket/archwire set up and the mean obtained. In the conventional metal brack-
ets, the elastomeric ligatures were removed and replaced with new elastomeric lig-
atures in each test. For removal and insertion of the elastomeric ligatures in the 
conventional brackets, an elastic tie applicator was used (Ref. 75.01.001, Morelli, 
Sorocaba, SP, Brazil)5,10,15.24.

The data did not comply with the presuppositions of a normal variance analysis. 
Therefore, the non-parametric Kruskal Wallis and Dunn tests were used for compari-
son between types of brackets and Wilcoxon tests for comparison between types of 
archwires. The Wilcoxon test was used because the same 30 test specimens were 
analyzed with the stainless steel archwires and those made of copper nickel titanium. 
The analyses were performed in the R Program (R Foundation for Statistical Comput-
ing, Vienna, Austria) considering the level of significance of 5%1,11,13,14. 



5

Barbosa et al.

Results 
In Table 1, it was possible to observe that the frictional force values were higher with 
copper nickel titanium than they were with stainless steel archwires, for the same 
type of bracket (p<0.05). When copper nickel titanium archwires were used, the active 
self-ligating brackets showed higher frictional force values than the other types 
(p<0.05), followed by the conventional brackets. Lower frictional force values were 
observed with passive self-ligating brackets (p<0.05). For stainless steel archwires, 
no significant difference was observed between conventional and active self-ligating 
brackets (p>0.05), but the passive self-ligating type presented significantly lower fric-
tional force values than the others (p<0.05).

Discussion
The hypothesis that self-ligated metal brackets would produce lower frictional force 
than conventional metal brackets was rejected. The hypothesis that the titanium 
nickel copper archwires would produce higher frictional force than the stainless steel 
wires was accepted.

The questions raised in our study reinforced the affirmations of other authors that the 
supposed advantage of lower friction in self-ligating brackets was still controversial, 
when compared with conventional brackets associated with archwires with rectangu-
lar sections, particularly when comparisons were made between active self-ligating 
brackets and the conventional types4,11,14,16,26,27. 

Our findings showed that the association of conventional and self-ligating active and 
passive brackets with copper nickel titanium archwires with rectangular 0.019 x 0.025 
inch sections presented higher friction values in the active self-ligating brackets, fol-
lowed by the conventional types. The lowest frictional force values were observed for 
the passive self-ligating brackets; these results corroborated the findings of previous 
studies that did not find lower frictional force with the use of self-ligating brackets. 

The elasticity of the copper nickel titanium archwire, with a rougher and more irregular 
surface associated with the pressure exerted by the clip of the self-ligating brackets 
could increase the surface of contact between the wire and the internal part of the 
slot. Consequently this would increase the frictional force, in agreement with previ-

Table 1. Median (minimum and maximum values) of frictional force (N) considering bracket and type 
of archwire 

Bracket
Archwire

Copper Nickel Titanium Stainless steel

Conventional 6.18 (4.38-6.86) Ab 4.96 (4.13-6.26)Ba

Active self-ligating 13.21 (10.58-15.35) Aa 9.56 (4.80-12.78)Ba

Passive self-ligating 0.52 (0.46-0.96) Ac 0.01 (0.00-0.02) Bb

Medians followed by different letters (capitals on horizontal lines and lower-case in vertical position) differ between 
them (p≤0.05)



6

Barbosa et al.

ous studies in which the composition of the copper nickel titanium archwire could 
increase the frictional force17,22,23,28. 

In conventional brackets associated with copper nickel titanium archwires, the friction 
would be lower due to the smaller area of contact of the ligature with the archwire, and 
also due to the lower pressure exerted by the elastic ligature on the archwire. These 
findings corroborated those of studies in which lower pressure exerted by the elastic 
ligatures were found, making the pressure smoother and diminishing the points of 
contact of the wire with the internal part of the slot21.  

The difference in composition between the material of the ligature and that of the clip 
could also have an influence on the friction. The lower friction values observed in the 
presence of passive self-ligating brackets would result from the smaller surface of 
contact between the archwire and internal part of the slot, resulting from the absence 
of pressure exerted by the clip of this bracket.  The findings of this study corroborated 
those of previous studies in which it was proved that the increase in contact surface 
increased the friction1,2,5,7,11,13,14,16,18,24.

The result of the present research showed that the combination between copper 
nickel titanium archwires associated with active self-ligating brackets generated 
higher frictional forces than those generated by the combination of this archwire with 
conventional brackets, disagreement with some reports in the literature, in which the 
low friction observed in self-ligating brackets was considered an advantage3,5.

Our findings corroborated the results found by researchers when they made a com-
parison between self-ligating and conventional brackets, in which the lower frictional 
resistance would only be observed when these brackets were combined with wires 
with smaller diameters. These results would be justified by the reduction in the sur-
face of contact between the slot and archwire1,2,5,11,13,14,24,26,29.  

The results of the present study revealed that active self-ligating brackets produced 
similar friction values when compared with conventional brackets with the use of 
stainless steel archwires with rectangular sections. This fact may be explained by the 
more polished, smoother surface and greater rigidity of this wire, so that in spite of the 
pressure exerted by the clips of the active self-ligating brackets, the contact surface 
of this wire would not be increased. In the case of conventional brackets, the elastic 
ligature would not produce sufficient force to increase the surface of contact at the 
bracket/archwire interface, corroborating the findings of previous studies in which the 
composition of the archwire and clip of the bracket were reported2,11,16,18,19,21. 

The lowest friction values in this study were observed in passive self-ligating brack-
ets, irrespective of the archwire used. This result corroborated the findings in the 
literature14,18. The lower friction in these brackets would be explained because 
of the smaller number of contacts between the archwire and bracket slot, since 
this system ends up creating a tunnel in which the archwire remains relatively 
free, thus transforming the bracket into a tube. This also explains why lower fric-
tional values were observed with archwires of smaller calibers; that is, the smaller 
the surface of contact, the lower would be the friction, reinforcing the results of 
previous researches1,2,11,13,18,24.



7

Barbosa et al.

The results of the present study contribute to the orthodontic practice of sliding 
mechanics, since the current literature does not show unanimity regarding the friction 
produced by wires of rectangular section of different compositions in self - ligating 
brackets. However, the results of this study have limitations because it is an in vitro 
study, suggesting that clinical studies are performed.

In conclusion, higher frictional forces were observed between copper and nickel 
titanium arches associated with active self-ligating brackets, while lower frictional 
forces were observed with the use of stainless steel arches associated with passive 
self-ligating brackets.

References

1. Muguruma T, Iijima M, Brantley WA, Ahluwalia KS, Kohda N, Mizoguchi I. Effects of third-order 
torque on frictional force of self-ligating brackets. Angle Orthod. 2014 Nov;84(6):1054-61. 
doi: 10.2319/111913-845.1.

2. Arash V, Rabiee M, Rakhshan V, Khorasani S, Sobouti F. In vitro evaluation of frictional forces of two 
ceramic orthodontic brackets versus a stainless steel bracket in combination with two types of 
archwires. J Orthod Sci. 2015 Apr-Jun;4(2):42-6. doi: 10.4103/2278-0203.156028.

3. Kannan MS, Murali RV, Kishorekumar S, Gnanashanmugam K, Jayanth V. Comparison of frictional 
resistance of esthetic and semiesthetic self-ligating brackets. J Pharm Bioallied Sci. 2015 Apr; 
7(Suppl 1): S116–20. doi: 10.4103/0975-7406.155852.

4. Higa RH, Semenara NT, Henriques JFC, Janson G, Sathler R, Fernandes TMF. Evaluation of force 
realesed by defletion of orthodontic wires in conventional and self-ligating brackets. Dental Press J 
Orthod. 2016 Nov-Dez;21(6):91-7. doi: 10.1590/2177-6709.21.6.091-097.oar.

5. Kumar D, Dua V, Mangla R, Solanki R, Solanki M, Sharma R. Frictional force released during sliding 
mechanics in nonconventional elastomerics and self-ligation an in vitro comparative study. 2016. 
Indian J Dent. 2016 Apr-Jun; 7(2); 60-5. doi: 10.4103/0975-962X.184652.

6. Fontes NM, Vedovello S, Vedovello M, Valdrighi H. Avaliação da força de atrito de bráquetes 
cerâmicos – estudo in vitro. Orthod Sci Pract. 2018;11(41):21-7.

7. Iafigliola SG, Neves JG, Godoi AP, Valdrighi HC, Custodio W, Vedovello Filho M. Evaluation of different 
types of self-ligating brackets guided by electromagnetic field simulator on rotational control. Braz J 
Oral Sci. 2018; 17:18885. doi: 10.20396/bjos.v17i0.8653852.

8. Moro A, Buche B, Morais ND, Topolski F, Correr GM. Sistema de bráquetes autoligáveis Empower. 
Orthod Sci Pract. 2018;11(42):29-43.

9. Shah PK, Sharma P, Goje SK. Comparative evaluation of frictional resistance of silver-corted 
stainless steel wires with uncorted stainless steel wires: An in vitro study. Contemp Clin Dent. 2018 
Sep;9(2):331-6. doi: 10.4103/ccd.ccd_405_18.

10. Braga LCC, Vedovello Filho M, Kuramae M, Valdrighi HC, Vedovello SAS, Correr AB. Fricção em 
braquetes gerada por fios de aço inoxidável, superelásticos com IonGuard e sem IonGuard. Dental 
Press J Orthod. 2011 Jul-Aug;16(4):41.1-6.

11. Pacheco MR, Oliveira DD, Smith Neto P, Jansen WC. Evaluation of friction in self-ligating brackets 
subjected to sliding mechanics: an in vitro study. Dental Press J Orthod. 2011 Jan-Feb;16(1):107-15. 
doi: 10.1590/S2176-94512011000100016.

12. Araújo RC, Bichara LM, Araújo AM, Normando D. Debris and friction of self-ligating and conventional 
orthodontic brackets after clinical use. Angle Orthod. 2015 Jul;85(4):673-7. doi: 10.2319/012914-80.1.

https://www.ncbi.nlm.nih.gov/pubmed/?term=10.2319/111913-845.1.
https://doi.org/10.2319/111913-845.1
https://www.ncbi.nlm.nih.gov/pubmed/?term=Arash V%5bAuthor%5d&cauthor=true&cauthor_uid=26020037
https://www.ncbi.nlm.nih.gov/pubmed/?term=Rabiee M%5bAuthor%5d&cauthor=true&cauthor_uid=26020037
https://www.ncbi.nlm.nih.gov/pubmed/?term=Rakhshan V%5bAuthor%5d&cauthor=true&cauthor_uid=26020037
https://www.ncbi.nlm.nih.gov/pubmed/?term=Khorasani S%5bAuthor%5d&cauthor=true&cauthor_uid=26020037
https://www.ncbi.nlm.nih.gov/pubmed/?term=Sobouti F%5bAuthor%5d&cauthor=true&cauthor_uid=26020037
https://www.ncbi.nlm.nih.gov/pubmed/26020037
https://doi.org/10.20396/bjos.v17i0.8653852
https://www.ncbi.nlm.nih.gov/pubmed/25251040


8

Barbosa et al.

13. Monteiro MRG, Silva LE, Elias CN, Vilella OV. Frictional resistance of self-ligating versus  
conventional brackets in different bracket-archwire-angle combinations. J Appl Oral Sci. 
2014;22(3):228-34. 

14. Geremia JR, Oliveira PS, Motta RHL. [Comparison of friction among self-ligating brackets and 
conventional brackets with different ligadures]. Orthod Sci Pract. 2015;8(29):30-7.

15. Seo Y-J, Lim B-S, Park YG, Yang I-H, Ahn S-J, Kim T-W, et al. Effect of self-ligating bracket  
type and vibration on frictional force and stick-slip phenomenon in diverse tooth displacement 
conditions: an in vitro mechanical analysis. Eur J Orthod. 2015 Oct;37(5):474-80. 
doi: 10.1093/ejo/cju060.

16. Szczupakowski A, Reimann S, Dirk C, Keilig L, Weber A, Jäger A, et al. Friction behavior of  
self-ligating and conventional brackets with different ligature systems. J Orofac 
Orthop. 2016 Jul;77(4):287-95. doi: 10.1007/s00056-016-0035-3.

17. Atik E, Akarsu-Guven B, Kocaderelis I. Mandibular dental arch changes with actives self-ligating 
brackets combined with different archwires. Niger J Clin Pract. 2018 May; 21(5):566-72. 
doi: 10.4103/njcp.njcp_94_17.

18. Gibson CG, Lin FC, Phillips C, Edelman A, Ko CC. Characterizing constraining forces  
in the alignment phase of orthodontic treatment. Angle Orthod. 2018 Jan; 88(1):67-74. 
doi: 10.2319/030117-159.1.

19. Kim KS, Han SJ, Lee TH, Park TJ, Choi S, Kang YG, Park KH. Surface analysis of 
metal clips of ceramic self-ligating brackets. Korean J Orthod. 2019 Jan;49(1):12-20. 
doi: 10.4041/kjod.2019.49.1.12.

20. Leal RC, Amaral FLB, França FMG, Basting RT, Turssi CP. Role of lubricants on friction 
between self-ligating brackets and archwires. Angle Ortho. 2014 Nov; 84(6):1049-53. 
doi: 10.2319/110513-805.1.

21. Henriques JFC, Higa RH, Semenara NT, Janson G, Fernandes TMF, Sathler R. Evaluation of 
deflection forces of orthodontic wires with different ligation types. Braz Oral Res. 2017 Jul; 31:49. 
doi: 10.1590/1807-3107BOR-2017.vol31.0049.

22. Gravina MA, Canavarro C, Elias CN, Chaves MGAM, Brunharo IH, Quintão CC.  Mechanical 
properties of Niti and CuNiti wires used in orthodontic treatment Part 2: Microscopic 
appraisal and metallurgical characteristics. Dental Press J Orthod. 2014 Jan-Fev;19(1):69-76. 
doi: 10.1590/2176-9451.19.1.069-076.oar.

23. Aydin B, Semisk NE, Koskan O. Evaluation of the alignment efficiency of nickel-titanium and 
copper-nickel-titanium archwires in patients undergoing orthodontic treatment over a 12-week 
period: A single-center, randomized controlled clinical trial. Korean J Orthod 2018;48(3):153-62. 
doi: 10.4041/kjod.2018.48.3.153.

24. Barbosa JA, Elias CN, Basting R. Evaluation of friction produced by self-ligating, 
conventional and Barbosa Versatile brackets. Rev Odontol UNESP. 2016 Mar-Apr;45(2):71-7. 
doi: 10.1590/1807-2577.09515.

25. Venâncio FR, Vedovello SAS, Tubel CAM, Degan VV, Lucato AS, Lealdim LN. Effect of elastomeric 
ligatures on frictional forces between the archwire and orthodontic bracket. Braz J Oral Sci. 2013 
Jan-Mar;12(1):41-5. doi: 10.1590/S1677-32252013000100009.

26. Castro R. ]Self-ligating brackets: efficiency versus scientific evidence]. Rev Dent Press Ortod Ortop 
Facial. 2009 Jul-Ago;14(4):20-4. Portuguese. doi: 10.1590/S1415-54192009000400002.

27. Carneiro GKM, Roque JA, Garcez Segundo AS, Suzuki H. Evaluation of stiffness 
and plastic deformation of active ceramic selfligating bracket clips after repetitive 
opening and closure movements. Dental Press J Orthod. 2015 Jul-Aug;20(4):45-50. 
doi: 10.1590/2176-9451.20.4.045-050.oar.

https://www.ncbi.nlm.nih.gov/pubmed/27220902
https://www.ncbi.nlm.nih.gov/pubmed/27220902


9

Barbosa et al.

28. Leite VV, Lopes MB, Gonini Júnior A, Almeida MR, Moura SK, Almeida RR. Comparison  
of frictional resistance between self-ligating and conventional brackets tied with elastomeric and 
metal ligature in orthodontic archwires. Dental Press J Orthod. 2014 May-Jun;19(3): 114-9.

29. Ehsania S, Mandichb MA, El-Bialy TH, Mirc CF. Frictional Resistance in Self-Ligating Orthodontic 
Brackets and Conventionally Ligated Brackets. A Systematic Review. Angle Orthod. 2009 
May;79(3):592-601. doi: 10.2319/060208-288.1.

https://www.ncbi.nlm.nih.gov/pubmed/?term=10.2319/060208-288.1