Oral Sciences n3


Braz J Oral Sci. 14(3):251-255

Original Article Braz J Oral Sci.
July | September 2015 - Volume 14, Number 3

Characterization of surface topography and
chemical composition of mini-implants

Luegya Amorim Henriques Knop1, Ana Prates Soares2, Ricardo Lima Shintcovsk1,
Lidia Parsekian Martins1, Luiz Gonzaga Gandini Jr. 1

1Universidade Estadual Paulista – UNESP, Araraquara Dental School, Department of Orthodontics and Pediatric Clinic, Araraquara, São Paulo, Brazil
2Universidade de São Paulo – USP, Hospital of Rehabilitation of Oralfacial Anomalies, Area of Prosthodontics, Bauru, São Paulo, Brazil

Correspondence to:
Luegya Amorim Henriques Knop

Rua Magno Valente, 110, Apartmento 1401 A, Pituba
CEP: 41810-620 Salvador, BA, Brasil

Phone: +55 71 3358 3338
E-mail: luegya@gmail.com

Abstract

Aim: To assess the surface topography and chemical composition of three brands of as-received
mini-implants (SIN®, Morelli®, and Conexao®). Methods: Twelve mini-implants of each brand
were analyzed by scanning electron microscopy and energy dispersive X-ray (EDX). Results:
There was no significant differences among SIN®, Morelli®, and Conexao® mini-implants comparing
their surface topography by visualization of SEM micrographs and analysis of scores. The EDX
analysis showed statistically significant difference among them for the amount of Ti, Al and V. Mini-
implants SIN® presented also N and O in their composition. Conclusions: In conclusion, the mini-
implants Morelli®, SIN® and Conexao® presented Ti as main component of the alloy. Remaining
components, such as Al and V, were also observed in all the analyzed brands, with differences
among them. Only SIN® mini-implants presented N and O. As far as surface topography is
concerned, there are no differences among the three brands of mini-implants.

Keywords: orthodontics; orthodontic anchorage procedures; titanium.

Introduction

Temporary anchorage devices (TADs) such as mini-implants act as skeletal
anchorage for Orthodontic movements. TADs are used when dental anchorage is
insufficient or a large amount of dental movement is required1. These devices are
widely used in Orthodontics offering excellent results and solving anchorage
problems that could not be addressed previously2 by overcoming the active versus
reactive forces generated during tooth movement3.

The optimal use of TAD should have some requirements such as small size,
placement without drilling, stability to withstand immediate and long term
loading, easy removal and comfort for the patient4. All these features, especially
the small dimensions of mini-implants, require a strong, high-grade titanium
alloy. Grade 5 Ti, also known as Ti-6Al-4V, is composed of 6% aluminum, 4%
nittro, 0.25% (maximum) iron, 0.2% (maximum) oxygen and Ti (remaining
percentage). The result is a combination of strength and fabricability 5. In
biological terms, grade 5 machined Ti promotes cell proliferation, good
cytocompatibility and cell adhesion4 although it does not provide a good-quality
osseointegration, which facilitates removal when needed6. The design of mini-
implants should feature a head to engage elastic bands or sprains, a smooth
transmucosal neck, an endossous self tapping body and a special groove in their
tip to be used for cutting or tapping the bone during insertion, which is called
lead angle1.

http://dx.doi.org/10.1590/1677-3225v14n3a15

Received for publication: August 26, 2015
Accepted: September 30, 2015



Manufacturers can create mini-implants in different
shapes and sizes. While they usually supply information on
outer diameter and length, chemical composition, depth, pitch,
lead angle of the thread as well as surface characteristics are
rarely provided7-8. The objective of this study was to assess
the surface topography and chemical composition of three
brands of mini-implants (Morelli®, SIN® and Conexao®) by
scanning electron microscopy (SEM) and energy dispersive
X-ray (EDX).

Material and methods

The sample was composed of 36 mini-implants of 3
different commercial brands: SIN® (São Paulo, SP, Brazil;
n= 12, 1.4 mm diameter, 8 mm length), Morelli® (Sorocaba,
SP, Brazil; n= 12, 1.5 mm diameter, 8 mm length), and
Conexao®; (Aruja, SP, Brazil; n= 12, 1.5 mm diameter, 8
mm length). All mini-implants were individually packaged
and used as received from the manufacturers. Packages were
only opened at the beginning of each analysis and carefully
handled in order to prevent contamination.

Analysis of Surface Topography by SEM
The specimens were fixed on SEM-stub-holders and

visualized through a field- emission scanning electron
microscope (FE-SEM) type 6301F (JEOL Ltd., Tokyo, Japan)
at 2kV with a working distance of 39mm and a small spot
size. Representative SEM micrographs of the head, body
and notch were taken from each sample of the different
brands. A single experienced examiner viewed the samples
at 30, 60 and 75x magnification to obtain the images after
brightness, contrast and focus adjustments. Surface texture
was observed and described in a qualitative manner,
comparing the groups.

Mini-implant topography was evaluated according to
the following scoring system: (0) absence of defects and
irregularities (like striations or protrusions); (1) presence
of defects in up to 25% of the mini-implant threads; (2)
presence of defects in up to 50% of the mini-implant
threads; (3) presence of defects in up to 75% of the mini-
implant threads; (4) presence of defects in all mini-implant
threads. The mean scores were analyzed statically by ANOVA
and Tukey’s test. Significance level was t at 5%.

Analysis of Chemical Composition by EDX
The chemical composition of the same all mini-

implants was analyzed by EDX at the same sites of the
topographical analysis. The EDX generated graphics
composed of the chemical compounds found in the device
a n d  t h e i r  r e s p e c t i v e  a m o u n t s .  T h e  i n f o r m a t i o n  w a s
g a t h e r e d  i n  a  s i n g l e  t a b l e ,  w h i c h  w a s  u s e d  f o r  t h e
s t a t i s t i c a l  a n a l y s i s .  D a t a  w e r e  a n a l y z e d  b y  A N O V A
f o l l o w e d  b y  T u k e y ’ s  p o s t t e s t  t o  d e t e c t  d i f f e r e n c e s
regarding the amount of the studied chemical elements
(C, Al, Ti, and V) in each mini-implant brand. Significance
level was t at 5%.

Results

Surface Topography
SIN® mini-implants were characterized by a clearly well-

polished and visible head (Figure 1), uniform unidirectional
threads, likely to be the result of machining. The machined
metal surface of SIN® appeared to be more satisfactory defined
with few structural defects among the 12 (Figure 2). Morelli®
mini-implants revealed uniform threads, but with some surface
defects, especially on the body. In addition, small
irregularities, such as striations, were also visible on a typical
machined metal surface (Figure 3). Conexao® mini-implants
presented no equivalent distance among the threads, with
larger distances among the threads on the body compared
with the head. The surface was homogenous, well polished,
and with few structural defects such as protrusion (Figure 4).
On the notch we observed a vertical design that is possibly
very relevant to bone drilling (Figure 5).

The three mini-implant groups received score 1 (mean), with
no statistically significant difference among the brands (p>0.05).

Fig. 1. SEM micrograph of the head of a SIN® mini-implant (x30)

Fig. 2.SEM micrograph of the body of a SIN® mini-implant showing a small defect
(x60)

Characterization of surface topography and chemical composition of mini-implants 1 7 11 7 11 7 11 7 11 7 1252252252252252

Braz J Oral Sci. 14(3):251-255



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Fig. 3. SEM micrograph of the body of a Morelli® mini-implant showing evident
surface roughness (x60)

Fig. 4. SEM micrograph of the body of Conexao® mini-implant. A well-polished
surface can be observed, with small defects (x60)

Fig. 5. SEM micrograph of the notch of Conexao® mini-implant (x75)

Chemical composition
Mini-implants from SIN®, Morelli® and Conexao® had

Ti, O, Al and V in their composition. Carbon and nitrogen
in smaller amounts were found as impurities in SIN® mini-
implants (Figure 6). It was not possible to conduct statistical
inference regarding elements N and O since their results for
all the studied samples by Morelli® and Conexao® were zero
(Table 1).

Discussion

Translational research is an important component of
orthodontic research since it can translate information from
the laboratory to enhance the outcomes of patients’
treatments3. The present research analyzed mini-implants
using SEM and EDX to verify their chemical composition
and surface design, two aspects of major relevance when
choosing the device to be used in a patient.

Titanium is a biocompatible metal with proper
mechanical9 and corrosion resistance10, which makes its
presence in the composition of mini-screws very important.

Mini-implants present a composition commercially
known as Ti-6al-4v with Al and V in addition to Ti. This
type of alloy provides the mini-implant with greater resistance
if compared with conventional implants with larger diameter.
In contrast, such formulation generates lower biological
compatibility decreasing the osseointegration phenomenon5.

All the analyzed brands presented Ti as main component,
and lower amounts of Al and V (score1). Conexao® and
Morelli® mini-implants presented Ti with quantities equivalent
to the respective manufacturers’ commercial descriptions.
Mini-implant SIN® presented lower Ti concentration with
statistically significant difference in relation to Morelli®
(p<0.0001) but no significance in relation to Conexao®.

Alsamak et al.5 identified foreigner mini-implants brands
with the presence of Ti, V, Al and O in quantities similar to
the ones found in our research, which corroborates the
composition of the Ti 5 grade alloy.

Park et al.11 stated that the osseointegration phenomenon
does not occur despite the presence of Ti in mini-implants,
which is a very important characteristic to facilitate their
removal.

SIN® presented other components, as N (1.59%), and O
(18.04%). Chin et al.12 studied 5 different mini-implants
associating their XPS survey spectra with a constitution of
primarily C, O and Ti, but also detecting traces of N, Ca, Fe,
Cr, Cu, Pb, Zn, and Si. The authors reported it as an apparent
problem of surface contamination. Silverstein et al. 1 3
evaluated three different brands of mini-implants by XPS
and observed that the elements found in all them were mainly
C, O, and Ti. They also found were other metals in small
amounts, and other trace elements. All three mini-screws
showed very different characteristics in surface composition.

Jofré et al.14 evaluated the 2-year survival rate of mini-
implants that came into contact with stainless steel prior to
insertion. SEM and EDX analyses revealed C and O in all
mini-implants.  Those that had contact with stainless steel,
additional elements were identified, including Si, Ca, Fe,
and Cr. The authors found that during the 2-year follow-up,

Characterization of surface topography and chemical composition of mini-implants

Braz J Oral Sci. 14(3):251-255



1 7 11 7 11 7 11 7 11 7 1254254254254254

C 2.33 (0.61) 2.32 (0.73) 2.40 (0.41) 0.9252
N 1.59 (0.77) 0.00 (0.00) 0.00 (0.00) —-
O 18.04 (2.96) 0.00 (0.00) 0.00 (0.00) —-
Al 4.61 (0.17) A 5.75 (0.18) B 5.32 (0.72) B <0.0001
Ti 72.88 (5.21) A 88.11 (0.64) B 77.98 (8.70) A <0.0001
V 3.15 (0.35) A 4.16 (0.23) B 4.01 (0.23) B <0.0001

Element                 SIN®              Morelli®          Conexao®                 p value
% mean (S.D.)          % mean (S.D.)        % mean (S.D.)        (ANOVA and Tukey’s test)

Table 1. Table 1. Table 1. Table 1. Table 1. Chemical elements detected in each group (n=12) of mini-implants
SIN®, Morelli® and Conexao®

Results were calculated as percentage and are presented in the table mean and standard deviation.
Different letters in rows mean statistically significant difference among the mini-implants (p<0.05)

Fig. 6. Graphic of the chemical composition of a SIN® mini-implant showing Ti, Al, V, C, O and N amounts.

one mini-implant failed (97.8% survival rate). So, the authors
concluded that stainless steel surgical guides does not seem
to generate contamination that compromises the survival of
mini-implants.

According to Vezeau et al.15, the contamination appeared
to occur during the manufacturing, packaging and handling
processes, as well as to result from sterilization procedures
involving undesirable located water condensation, and the
heterogeneity of a mixed sterilizer load in an institutional
setting. Morra et al.16 affirm that airborne N contaminations
in the implants are unavoidable and usual to a reasonable
level of inadequate surface treatment and implant handling
(during packaging, for example). This type of surface
pollution is typically inhomogeneous surrounding the
implant, and should not be mistaken with controlled chemical
or biochemical modifications.

Generally, as-received mini-implants can present high
amounts of C, indicating high level of particulate
contamination on oxide surfaces12. The present study revealed
all the groups with small quantity of C with non-statistically
significant difference among the tested brands.

The success of orthodontic mini-plants depends on the

metallurgy applied in their production, which is especially
associated with a great quality alloy surcharge and its proper
handling. During the process of alloy turning to produce the
mini-implants, metallurgical contamination must be
prevented17. Further studies should investigate whether the
contamination of mini-implants surfaces interferes in their
biocompatibility or in the stability of their clinical use. A
systematic review by Schatzle18 presented 363 or 15.3%
failures out of 2374 mini-screws inserted in 1196 patients.
The contamination of the mini-implant surface is a possible
cause of clinical failure.

The topography analysis revealed that the three brands
presented some type of structural defect such as protrusion
or striated surfaces, especially in the body, in addition to
some roughness. In this study, it was given a score to quantify
the surface topography homogeneity. All brands presented
score 1, with no statistical difference among them. It is not
certain how decisive the interference of such structural
alterations are to the success of the mini-implant; although
Burmann et al.19 states that differences in mini-implant design
and the presence of surface irregularities may influence the
effectiveness of orthodontic anchorage.

Characterization of surface topography and chemical composition of mini-implants

Braz J Oral Sci. 14(3):251-255



255255255255255

According to Melsen20 the head of mini-implants should
be well polished to avoid the accumulation of biofilm on
local tissues. This characteristic also decreases the possibility
of causing injuries to the surrounding mucous membrane
consequently increasing the possibility of success during
the treatment. All the studied brands presented favorable
characteristics in the area enabling their clinical use.

Further studies should be carried out in order to assess
those mini-implants in vivo, which could enable their clinical
use with improved safety.

In conclusion, the mini-implants by SIN®, Morelli® and
Conexao® presented Ti as main component of the alloy; the
remaining components, such as Al and V, were also observed
in all the analyzed brands. SIN® was the only brand presenting
mini-implant with chemical elements O and N. All mini-
implants presented structural defects in the SEM analysis,
with no differences among the groups.

Acknowledgements

We would like to thank the Osvaldo Cruz Foundation
(Fiocruz), especially the Electron Microscopy Service, for
supporting our research and providing a scanning electron
microscope.

References

1. Prabhu J, Cousley RR. Current products and practice: bone anchorage
devices in orthodontics. J Orthod. 2006; 33: 288-307.

2. Kalarickal B. Group distal movement of teeth using micro-screw-implant
anchorage-a case report. J Clin Diagn Res. 2014; 8: 26-9.

3. Rossouw E. Translational mini-screw implant research. J Orthod. 2014;
41: s8-s14.

4. Galli C, Piemontese M, Ravanetti F, Lumetti S, Passeri G, Gandolfini M,
et al. Effect of surface treatment on cell responses to grades 4 and 5
titanium for orthodontic mini-implants. Am J Orthod Dentofacial Orthop.
2012; 141: 705-14.

5. Alsamak S, Psomiadis S, Gkantidis N. Positional guidelines for orthodontic
mini-implant placement in the anterior alveolar region: a systematic review.
Int J Oral Maxillofac Implants. 2013; 28: 470-9.

6. Mizrahi E, Mizrahi B. Mini-screw implants (temporary anchorage devices):
orthodontic and pre-prosthetic applications. J Orthod. 2007; 34: 80-94.

7. Katiæ V, Kamenar E, Blaževiæ D, Spalj S. Geometrical design
characteristics of orthodontic mini-implants predicting maximum insertion
torque. Korean J Orthod. 2014; 44: 177-83.

8. Walter A, Winsauer H, Marcé-Nogué J, Mojal S, Puigdollers A. Design
characteristics, primary stability and risk of fracture of orthodontic mini-
implants: pilot scan electron microscope and mechanical studies. Med
Oral Patol Oral Cir Bucal. 2013; 18: e804-10.

9. Gonçalves JP, Shaikh AQ, Reitzig M, Kovalenko DA, Michael J, Beutner
R, et al. Detonation nanodiamonds biofunctionalization and immobilization
to titanium alloy surfaces as first steps towards medical application. Beilstein
J Org Chem. 2014; 26: 2765-73.

10. Carlsson L, Rostlund T, Albretsson B, Albretsson T, Branemark PI.
Osseointegration of titanium implants. Acta Orthop Scand. 1986; 57: 385-9.

11. Park HS, Kwon TG, Sung JH. Nonextraction treatment with microscrew
implants. Angle Orthod. 2004; 74: 539-49.

12. Chin MYH, Sandham A, de Vries J, Van der Mei HC, Busscher HJ.
Biofilm formation on surface characterized micro-implants for skeletal
anchorage in orthodontics. Biomaterials. 2007; 28: 2032-40.

13. Silverstein J, Barreto O, França R. Miniscrews for orthodontic anchorage:
nanoscale chemical surface analyses. Eur J Orthod. 2015; 13. pii: cjv007.

14. Jofré J, Conrady Y, Carrasco C. Survival of splinted mini-implants after
contamination with stainless steel. Int J Oral Maxillofac Implants. 2010;
25: 351-6.

15. Vezeau PJ, Koorbusch GF, Draughn RA, Keller JC. Effects of multiple
sterilization on surface characteristics and in vitro biologic responses to
titanium. J Oral Maxillofac Surg 1996; 54: 738-46.

16. Morra M, Cassinelli C, Bruzzone G, Carpi A, Di Santi G, Giardino R, et
al. Surface chemistry effects of topographic modification of titanium dental
implant surfaces: 1. Surface analysis. Int J Oral Maxillofac Implants.
2003; 18: 40-5.

17. Carano A, Velo S, Leone P, Siciliani G. Clinical applications of the miniscrew
anchorage system. J Clin Orthod. 2005; 39: 9-24.

18. Schätzle M, Männchen R, Zwahlen M, Lang NP. Survival and failure
rates of orthodontic temporary anchorage devices: a systematic review.
Clin Oral Implants Res. 2009; 20: 1351-9.

19. Burmann PF, Ruschel HC, Vargas IA, de Verney JC, Kramer PF. Titanium
alloy orthodontic mini-implants: scanning electron microscopic and
metallographic analyses. Acta Odontol Latinoam. 2015; 28: 42-7.

20. Melsen B. Mini-implants, where are we? J Clin Orthod. 2005; 39: 539-47.

Characterization of surface topography and chemical composition of mini-implants

Braz J Oral Sci. 14(3):251-255