Metallographic analysis of the internal microstructure of orthodontic mini-implants

Cotrim-Ferreira, Flávio Augusto; Quaglio, Camila Leite; Peralta, Rubén Patricio Vásquez; Carvalho, Paulo Eduardo Guedes; Siqueira, Danilo Furquim

doi:10.1590/s1806-83242010000400011

Cited by 17 publications

(16 citation statements)

References 18 publications

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“…14,23 According to the manufacturers, Neodent miniimplants are rated at grade 5 Ti6Al4V in their chemical composition (ASTM-136), while the Morelli mini-implants rate grade 23 Ti6Al4V (ASTM-136). In the present study, chemical analysis showed that heavy metals were present in both brands of mini-implants, Previous studies have shown that osteoblasts proliferate on the alloys studied 11,15,24 and that the mini-implants used for temporary anchorage in orthodontics may partially osseointegrate. 19,20 Also, both implant and thread design may influence insertion and removal torques, highlighting the importance of selecting an adequate design according to cortical bone thickness.…”

Section: Discussionsupporting

confidence: 57%

“…This titanium alloy, known as grade 5 Ti, confers higher fatigue resistance than does cp Ti, yet maintains properties such as resistance to corrosion and low toxicity. 11,14,15 The chemical and topographic features of miniimplant surfaces are regarded as important in terms of their interface with bone cells because of their high quality of osseointegration, 13 since osteoblast morphology can be influenced by composition and type of surface treatment. 16 If corrosion sets in because of the chemical composition of the alloy, encapsulated tissue may be formed secondarily to the release of metallic ions and other byproducts of corrosion, as well as ionic contamination of organic tissues, thus compromising cell adhesion.…”

Section: Introductionmentioning

confidence: 99%

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In vitro study of human osteoblast proliferation and morphology on orthodontic mini-implants

Bueno

Basting

2015

The Angle Orthodontist

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Section: Discussionsupporting

confidence: 57%

Section: Introductionmentioning

confidence: 99%

In vitro study of human osteoblast proliferation and morphology on orthodontic mini-implants

Bueno

Basting

2015

The Angle Orthodontist

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“…Even though the proportion of titanium was similar in all commercial brands, titanium alloys can have different amounts of alpha-phase and beta-phase titanium, possibly due to differences in the manufacturing process of the alloy. For instance, Cotrim-Ferreira et al (2010) 11 showed that there were quantitative differences in alpha-phase and beta-phase titanium in mini-implant alloys from three commercial brands (SIN, Dewimed, and CON), even though they were within the guidelines of the "Technical Committee of European Titanium Producers" described in Publication ETTC-2.…”

Section: Discussionmentioning

confidence: 99%

“…To meet these requirements, the titanium alloy (Ti-6Al-4V) chosen for manufacture of mini-implants incorporates aluminum (Al) and vanadium (V) into its composition along with commercially pure titanium (cpTi) 10 . Ti-6Al-4V alloy has higher fatigue resistance than (cpTi), while having the same corrosion resistance and low toxicity 11 . The amount of each component in the alloy, in addition to the manufacturing quality, can alter its mechanical properties such as hardness and resiliency, which are responsible for the fracture resistance of the mini-implant.…”

Section: Introductionmentioning

confidence: 99%

Chemical analysis and Vickers hardness of orthodontic mini-implants

Feitoza¹,

Oliveira²,

Boeck³

et al. 2015

Braz. J. Oral Sci.

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Orthodontic mini-implants are used in clinical practice to provide efficient and aesthetically-pleasing anchorage. Aim: To evaluate the hardness (Vickers hardness) and chemical composition of miniimplant titanium alloys from five commercial brands. Methods: Thirty self-drilling mini-implants, six each from the following commercial brands, were used: Neodent (NEO), Morelli (MOR), Sin (SIN), Conexão (CON), and Rocky Mountain (RMO). The hardness and chemical composition of the titanium alloys were performed by the Vickers hardness test and energy dispersive X-ray spectroscopy, respectively. Results: Vickers hardness was significantly higher in SIN implants than in NEO, MOR, and CON implants. Similarly, VH was significantly higher in RMO implants than in MOR and NEO ones. In addition, VH was higher in CON implants than in NEO ones. There were no significant differences in the proportions of titanium and aluminum in the mini-implant alloy of the five commercial brands. Conversely, the proportion of vanadium differed significantly between CON and MOR/NEO implants. Conclusions: Mini-implants of different brands presented distinct properties of hardness and composition of the alloy.

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“…They can be manufactured using several materials, including commercially pure titanium (Ti cp), titanium alloy (Ti-6Al-4V) and stainless steel [3,4]. In terms of features, these materials should be non-toxic, biocompatible, present favorable mechanical properties, be able to withstand stress, deformation and corrosion [5,6], and not induce adverse local or biological responses [7,8]. In this respect, these devices should not exhibit surface degradation over time, so as to ensure very low or no-ion release and good corrosion resistance [6,9].…”

Section: Introductionmentioning

confidence: 99%

Corrosion and Micromorphological Analysis of Temporary Stainless Steel and Titanium Alloy Anchorage Devices

et al. 2020

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The aim of this study was to compare the surface micromorphology and corrosion resistance of different temporary anchorage devices (TADs) composed of titanium alloy (SIN®) and stainless steel (DAT Steel® and Bio Ray®). Ten samples of each TAD were submitted to qualitative analyses using energy-dispersive and scanning electronic microscopy before and after immersion in artificial saliva (1500 ppm of fluoride) for 30 days. The chemical analysis was done by X-ray fluorescence, and the corrosion tests were performed by electrochemical means (open circuit potential-OCP, potentiostat, and electrochemical impedance spectroscopy-EIS, using anodic potentiodynamic polarization curves). Passive film resistance (PFR) and corrosion current were established. The corrosion rate was determined by the mass loss test. Greater smoothness and fewer machining defects were observed for the stainless steel TAD before artificial saliva immersion. Comparatively, higher corrosion resistance was found for titanium alloy TAD after immersion in saliva. There was no release of ions into the TAD when immersed in artificial saliva. ANOVA and Tukey tests showed that OCP (V) was significantly lower for the titanium alloy TAD (p = 0.030) than the stainless steel brands. E pite (V) and E pite −OCP (V) were significantly higher for the titanium alloy TAD (p = 0.0009 and p = 0.0005, respectively). Stainless steel TADs presented lower roughness surface than titanium alloy TAD, although the latter presented higher corrosion resistance than the former.

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Metallographic analysis of the internal microstructure of orthodontic mini-implants

Cited by 17 publications

References 18 publications

In vitro study of human osteoblast proliferation and morphology on orthodontic mini-implants

In vitro study of human osteoblast proliferation and morphology on orthodontic mini-implants

Chemical analysis and Vickers hardness of orthodontic mini-implants

Corrosion and Micromorphological Analysis of Temporary Stainless Steel and Titanium Alloy Anchorage Devices

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