2 3...on implant surfaces: a review of current knowledge and opinions. wennerberg a, albrektsson t....
TRANSCRIPT
2 3
The future is now
I m p l a n t S y s t e mw w w. s i n p l a n t . c o m
HAnano ® Surface
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SimplicityInnovationNanotechnology
2 3
HAnano® SURFACEThe goal of continuous search for implant surfaces
improvement is to boost scar response quality and hasten bone response, creating the possibility of an aesthetic and functional rehabilitation in short time compared to what is conventionally proposed25. Hydroxyapatite (HA), which is the main mineral present in the natural bone structure, when applied on the surface of nanostructured titanium implants, forms a homogeneous and stable coating func-tioning as a scar catalyst that speeds up Osseointegration when compared to conventional surfaces. This coating dif-fers significantly in thickness, application method, clinical predictability and scientific support when compared to the HA surfaces used in the past*.
From 2005 on, HAnano® surfaces have been develo-ped by researchers from leading universities in Gothenburg (Sweden). Scientists from several countries have tested and approved its effectiveness, the results of which have been published in dozens of articles in world-renowned scientific journals1;3;4. The HAnano® coating is formed by hydroxyapatite nanocrystals, with size and shape similar to those of human bone, sintered on a microrough titanium measuring 20 nm thick that promotes a change on surface energy, increasing the hydrophilicity and providing substrate that stimulates a greater osteoblasts multiplication25;†. These crystals are applied to the titanium implant surface after a chemical tre-atment with double thermal acid attack (DAA), which brin-gs a series of benefits to the Unitite implants, such as the healing process acceleration, high hydrophilicity, increased bone formation (BIC - Bone Implant Contact ) and the quality improvement of the new bone formed (BAFO - Bone Area Fraction Occupancy), keeping the original implant microto-pography 24;27.
The HAnano® present on the surface of the Unitite im-plant has shown an improvement in scar response in mole-cular tests of signal transduction, where the proteins invol-ved in the scar process recorded a substantial increase in concentration, presenting the coating positive effect on the interaction with the pre-osteoblastic cells36. Likewise, there was an increase in the concentration of important osteoge-nic markers, such as alkaline phosphatase and ostecalcin, in a clear signaling of the mineralization process acceleration §.
Among the most relevant aspects, with the greatest clinical significance, is the bone mechanical quality which is
The positive effects of HAnano's surface have been evaluated and proven in numerous scientific publications, some
examples of publications are:
SCIENTIFIC PUBLICATIONS
formed around this highly hydrophilic Unitite surface, which derives from the resulting ionic potential of the HAnano®.
It has been shown that the bone mechanical pro-perties, such as modulus of elasticity and hardness in the fraction of bone area formed (BAFO), increased significantly HAnano® 16;14;27, not only in the vicinity of the bone implant interface (BIC), but also within the healing chambers and es-pecially in distant areas of the implants. According to a in vivo study, published by Coelho and collaborators, there was an increase of +% BIC and +% BAFO - indexes superior to traditional surfaces implants¶ .
A comparative study published by Wennerberg A. **, assessing different types of surfaces in animals, has shown that HAnano® greatly improves the quality of the bone formed and accelerates the healing process. Following the same line of research, Cavalcanti and colleagues compared grade IV titanium implants without surface treatment, with a double acid attack and with HAnano® coating; and the result demons-trated complete mineralization of the latter in 28 days45. Other clinical studies recently published by Pessoa and col-leagues, evaluating systemically healthy patients with no local bone involvement, point to the same result in humans, emphasizing the need to associate an ideal macrogeometry, microgeometry and nanometric surface to achieve satisfac-tory results in time as in the case of the Unitite implant29.
The resulting ionic potential of the HAnano® coating as-sociated with its microtopography generate an increase in the titanium surface energy, making the implant highly hydrophi-lic, which guarantees the presence of blood and its compo-nents in the healing chamber, in additon to generating greater adsorption of the proteins involved in the Osseointegration process, demonstrating its bioactive potential.
Unlike technologies used in past decades, the HAnano® surface coating has a nanometric thickness that does not alter its surface roughness, is reabsorbable and functions as a scar catalyst so that the bone tissue can in-teract directly with the titanium in shorter periods of time. The use of a patented and proven method of coating appli-cation ensures its stability and surface homogeneity †, which is paramount to ensure its use in several types of bone densi-ty and to guarantee the success of rehabilitation treatment with high levels of predictability.
"NANO HYDROXYAPATITE STRUCTURES INFLUENCE EARLY BONE FORMATION."
"THE EFFECT OF CHEMICAL AND NANOTOPOGRAPHICAL MODIFICATIONS ON THE EARLY STAGES OF OSSEOINTEGRATION."
Meirelles L, Arvidsson A, Andersson M, Kjellin P, Albrektsson T, Wennerberg A.
Journal of Biomedical Materials Research Part A Volume 87A, Issue 2,2008, pp. 299-307
Meirelles L, Currie F, Jacobsson M, Albrektsson T, Wennerberg A.
The International Journal of Oral and Maxillofacial Implants Volume 23, Issue 4, 2008, pp. 641-647
*. HA particles can be released from well-fixed HA-coated stems: histopathology of biopsies from 20 hips 2-8 years after implantation. Røkkum M, Reigstad A, Johansson CB. Acta Orthop Scand 73 (3), 298-306. 6 2002
†. On implant surfaces: a review of current knowledge and opinions. Wennerberg A, Albrektsson T. Int J Oral Maxillofac Implants. 2010 Jan-Feb;25(1):63-74.
§. Different patterns of bone fixation with hydroxyapatite and resorbable CaP coatings in the rabbit tibia at 6, 12, and 52 weeks. Reigstad O, Johansson C, Stenport V, Wennerberg A, Reigstad A, Røkkum M. J Biomed Mater Res B Appl Biomater. 2011 Oct;99(1):14-20.
¶. Biomechanical and bone histomorphologic evaluation of four surfaces on plateau root form implants: an experimental study in dogs. Coelho PG, Granato R, Marin C, Bonfante EA, Janal MN, Suzuki M. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2010 May;109(5):e39-45.
**. A histomorphometric and removal torque study of screw-shaped titanium implants with three different surface topographies. Wennerberg A, Albrektsson T, Andersson B, Krol JJ. Clin Oral Implants Res. 1995 Mar;6(1):24-30.
4 5
UNITITE PRIMEDiameter (mm)
8.5
10.0
11.5
13.0
15.0
Length (mm)
3.5
4.3
5.0
UNITITE SLIMDiameter (mm)
10.0
11.5
13.0
Length (mm)
2.9
UNITITE COMPACTDiameter (mm)
4.0
5.0
6.0
Length (mm)
5.0
6.0
7.0
PRIME, SLIM and COMPACT: three implant lines, which meet the most
diverse needs.
High hydrophilicity: HAnano® surface combined with implant
macrogeometry expands surface energy and accelerates the
Osseointegration process.
Healing chambers: while the larger coils touch the bone, guaranteeing
primary stability, the smaller coils create a chamber that increases the
contact between the clot and the implant, favoring the speed and quality
of the healing process.
Hybrid Macrogeometry: at first, the implant presents a cylindrical shaped
body and becomes progressively conical, suitable for all bone densities.
4 5
6 7
SURGICAL
BONE EXPANDER
The same kit fits the entire Unitite line.
SAFE DRILL
ROTARY EXPANDER
SHORT DRILLOSTEOTHES
PROSTHETIC
BONE GRAFTSINUS LIFT
OUR KITS
Color coded to simplify clinical use.
Small number of drills
needed for osteotomy.
Torque wrench with torque gauge.
DLC* coated drills: increased durability and cutting power.
Duo-digital key included
* Diamond like carbon
8 9
CODE DIAM. LENGTH
3.5 8.5
3.5 10.0
3.5 11.5
3.5 13.0
3.5 15.0
4.3 8.5
4.3 10.0
4.3 11.5
4.3 13.0
4.3 15.0
5.0 8.5
5.0 10.0
5.0 11.5
5.0 13.0
5.0 15.0
CODE DIAM. LENGTH
CODE
CODE
CIMU 3308 3.3 0.8
CIMU 3315 3.3 1.5
CIMU 3325 3.3 2.5
CIMU 3335 3.3 3.5
CIMU 3345 3.3 4.5
CIMU 3355 3.3 5.5
CIMU 4508 4.5 0.8
CIMU 4515 4.5 1.5
CIMU 4525 4.5 2.5
CIMU 4535 4.5 3.5
CIMU 4545 4.5 4.5
CIMU 4555 4.5 5.5
TMFMU
ANMU
CODE DIAM.
CODE
CPTMU 3501-H
CPTMU 3502-H
CPTMU 3503-H
CPTMU 3504-H
CPTMU 4501-H
CPTMU 4502-H
CPTMU 4503-H
CPTMU 4504-H
CODE DIAM. LENGTH EUCLAMU 3501-H 3.8 1.0
EUCLAMU 3502-H 3.8 2.0
EUCLAMU 3503-H 3.8 3.0
EUCLAMU 3504-H 3.8 4.0
EUCLAMU 4501-H 4.5 1.0
EUCLAMU 4502-H 4.5 2.0
EUCLAMU 4503-H 4.5 3.0
EUCLAMU 4504-H 4.5 4.0
LENGTH 1.0
2.0
3.0
4.0
1.0
2.0
3.0
4.0
1.8PTM 181.8PTM 1816
For temporary cylinder
Immediate loading: Recommend torque above 45 N.cm.
Early loading (as from 28 days)**: Recommended torque from 30 to 45 N.cm.
Late loading: Torque less than 30 N.cm.
* In bone types I and II the bone tap is required to not exceed the recommended torque, and ensure the correct healing process. ** Contraindicated for patients with diabetes, smokers, pos extraction alveolus, active periodontaldisease and osteoporosis. Also in patients during radiotherapy and chemotherapy.
Analog
Closed tray transfer
Healing capTemporary
titanium cylinder Plastic/Co-Cr UCLA Retaining screw
Includes cover screw of 2.0 mm.
Recommended from 1.5 mm to 2.0 mm
For installation at bone level it is necessary to use cover screw TIMU 0012.
Indicated for all type of bones.
Internal angle of 11.5°.
All measurements in mm
UCM 3585N
UCM 3510N
UCM 3511N
UCM 3513N
UCM 3515N
UCM 4385N
UCM 4310N
UCM 4311N
UCM 4313N
UCM 4315N
UCM 5085N
UCM 5010N
UCM 5011N
UCM 5013N
UCM 5015N
Maximum Torque: 60 N.cm.
Speed of the initial drills: 1,200 rpm.
Speed of the drills 2.7 to 5.0mm: 800 rpm.
Speed of the bone tap: 20 rpm*.
Insertion speed: 20 to 40 rpm.
CODE
TMAMU
Open traytransfer
20 N.cm 20 N.cm 20 N.cm
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
DIAM.
3.5
3.5
3.5
3.5
4.5
4.5
4.5
4.5
For UCLA
PRIM
E
* Coming soon. Check availability with your distributer.
UNITITE PRIMERESTORATIVE OPTIONSTEMPORARY/CEMENTED/SCREW RETAINED
10 11
DIAM. DIAM. CODECODE LENGTH
CODE DIAM. LENGTH
CPSIT 3340 3.3 4.0
CPSIT 3360 3.3 6.0
CPSIT 4540 4.5 4.0
CPSIT 4560 4.5 6.0
CODE DIAM. LENGTH
3.3 4.0
3.3 6.0
4.5 4.0
4.5 6.0
CODE DIAM. LENGTH
3.5 8.5
3.5 10.0
3.5 11.5
3.5 13.0
3.5 15.0
4.3 8.5
4.3 10.0
4.3 11.5
4.3 13.0
4.3 15.0
5.0 8.5
5.0 10.0
5.0 11.5
5.0 13.0
5.0 15.0
DIAM. LENGTH
3.3 0.8
3.3 1.5
3.3 2.5
3.3 3.5
3.3 4.5
3.3 5.5
4.5 0.8
4.5 1.5
4.5 2.5
4.5 3.5
4.5 4.5
4.5 5.5
CODE DIAM. TRANSMUCOSAL LENGTH
CEMENTATION LENGTH
3.3 0.8 4.0
3.3 1.5 4.0
3.3 2.5 4.0
3.3 3.5 4.0
3.3 4.5 4.0
3.3 5.5 4.0
3.3 0.8 6.0
3.3 1.5 6.0
3.3 2.5 6.0
3.3 3.5 6.0
3.3 4.5 6.0
3.3 5.5 6.0
4.5 0.8 4.0
4.5 1.5 4.0
4.5 2.5 4.0
4.5 3.5 4.0
4.5 4.5 4.0
4.5 5.5 4.0
4.5 0.8 6.0
4.5 1.5 6.0
4.5 2.5 6.0
4.5 3.5 6.0
4.5 4.5 6.0
4.5 5.5 6.0
CODE DIAM. HIGHER TRANSMUCOSALLENGTH
LOWERTRANSMUCOSAL LENGTH
CEMENTATION LENGTH
3.3 2.6 1.5 4.0 17°
3.3 3.6 2.5 4.0 17°
3.3 4.6 3.5 4.0 17°
3.3 3.15 1.5 4.0 30°
3.3 4.15 2.5 4.0 30°
3.3 5.15 3.5 4.0 30°
3.3 2.6 1.5 6.0 17°
3.3 3.6 2.5 6.0 17°
3.3 4.6 3.5 6.0 17°
3.3 3.15 1.5 6.0 30°
3.3 4.15 2.5 6.0 30°
3.3 5.15 3.5 6.0 30°
4.5 3.0 1.5 4.0 17°
4.5 4.0 2.5 4.0 17°
4.5 5.0 3.5 4.0 17°
4.5 3.75 1.5 4.0 30°
4.5 4.75 2.5 4.0 30°
4.5 5.75 3.5 4.0 30°
4.5 3.0 1.5 6.0 17°
4.5 4.0 2.5 6.0 17°
4.5 5.0 3.5 6.0 17°
4.5 3.75 1.5 6.0 30°
4.5 4.75 2.5 6.0 30°
4.5 5.75 3.5 6.0 30°
UCM 3585N
UCM 3510N
UCM 3511N
UCM 3513N
UCM 3515N
UCM 4385N
UCM 4310N
UCM 4311N
UCM 4313N
UCM 4315N
UCM 5085N
UCM 5010N
UCM 5011N
UCM 5013N
UCM 5015N
CODE
CIMU 3308
CIMU 3315
CIMU 3325
CIMU 3335
CIMU 3345
CIMU 3355
CIMU 4508
CIMU 4515
CIMU 4525
CIMU 4535
CIMU 4545
CIMU 4555
All measurements in mm
Healing cap Analog
One-Piece StraightUniversal Abutment
AISIT 334008
AISIT 334015
AISIT 334025
AISIT 334035
AISIT 334045
AISIT 334055
AISIT 336008
AISIT 336015
AISIT 336025
AISIT 336035
AISIT 336045
AISIT 336055
AISIT 454008
AISIT 454015
AISIT 454025
AISIT 454035
AISIT 454045
AISIT 454055
AISIT 456008
AISIT 456015
AISIT 456025
AISIT 456035
AISIT 456045
AISIT 456055
Angled universal abutment*
PolyacetalImpression Transfer
APASIT 341715
APASIT 341725
APASIT 341735
APASIT 343015
APASIT 343025
APASIT 343035
APASIT 361715
APASIT 361725
APASIT 361735
APASIT 363015
APASIT 363025
APASIT 363035
APASIT 441715
APASIT 441725
APASIT 441735
APASIT 443015
APASIT 443025
APASIT 443035
APASIT 461715
APASIT 461725
APASIT 461735
APASIT 463015
APASIT 463025
APASIT 463035
TSIT 3340 3.3
TSIT 3360 3.3
TSIT 4540 4.5
TSIT4560 4.5
3.3 4.0
3.3 6.0
4.5 4.0
4.5 6.0
LENGTH
4.0
6.0
4.0
6.0
ASIT 3340
ASIT 3360
ASIT 4540
ASIT 4560
ANG.
Temporary acrylic cylinder
Calcinable polyacetal cylinder
CCSIT 3340
CCSIT 3360
CCSIT 4540
CCSIT 4560
CODE
**Two-Pieces StraightUniversal Abutment
APSIT 334008
APSIT 334015
APSIT 334025
APSIT 334035
APSIT 334045
APSIT 334055
APSIT 336008
APSIT 336015
APSIT 336025
APSIT 336035
APSIT 336045
APSIT 336055
APSIT 454008
APSIT 454015
APSIT 454025
APSIT 454035
APSIT 454045
APSIT 454055
APSIT 456008
APSIT 456015
APSIT 456025
APSIT 456035
APSIT 456045
APSIT 456055
10 N.cm
PRIM
E
* Use hexagonal driver 0.9 mm
** Coming soon. Check availability with your distributer.
10 N.cm20 N.cm
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
UNITITE PRIMEUNIVERSAL ABUTMENT - PRE-MADE POSTSCEMENTED RETAINED RESTORATIONS
12 13
All measurements in mm
CODE DIAM LENGTH
3.5 8.5
3.5 10.0
3.5 11.5
3.5 13.0
3.5 15.0
4.3 8.5
4.3 10.0
4.3 11.5
4.3 13.0
4.3 15.0
5.0 8.5
5.0 10.0
5.0 11.5
5.0 13.0
5.0 15.0
CODE
CODE
CODE
PRH 30
LENGTH
3.0
CODE
ANAC
CODE
TMFA 4800
TMFA 4806
Healing cap
UCM 3585N
UCM 3510N
UCM 3511N
UCM 3513N
UCM 3515N
UCM 4385N
UCM 4310N
UCM 4311N
UCM 4313N
UCM 4315N
UCM 5085N
UCM 5010N
UCM 5011N
UCM 5013N
UCM 5015N
CODE DIAM LENGTH
3.3 0.8
3.3 1.5
3.3 2.5
3.3 3.5
3.3 4.5
3.3 5.5
4.5 0.8
4.5 1.5
4.5 2.5
4.5 3.5
4.5 4.5
4.5 5.5
CIMU 3308
CIMU 3315
CIMU 3325
CIMU 3335
CIMU 3345
CIMU 3355
CIMU 4508
CIMU 4515
CIMU 4525
CIMU 4535
CIMU 4545
CIMU 4555
Conical abutment AnalogConical abutment protector
Retainingscrew
Polishing protector
Open tray transfer
Temporarytitanium cylinder
Closed tray transfer
Calcinable Co-Cr cylinder
CODE DIAM LENGTH
4.8 0.8
4.8 1.5
4.8 2.5
4.8 3.5
4.8 4.5
4.8 5.5
CODE
PPAC 01
ACMU 4808
ACMU 4815
ACMU 4825
ACMU 4835
ACMU 4845
ACMU 4855
PA 4855
Laboratoryscrew
CODE
TMAA 4800
TMAA 4806 CODE
CODE
CPAC 06-3
CPAC 00-3
CALE 06-3 Cobalt-chrome
CALE 00-3 Cobalt-chrome
PL 1405 Short
PTMA 13-1 Long
20 N.cm
10 N.cm
10 N.cm
10 N.cm
PTA 4800-3
PTA 4806-3
PRIM
E
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
UNITITE PRIMECONICAL ABUTMENTSINGLE/MULTIPLE SCREW RETAINED RESTORATIONS
14 15
PRIM
E
Retainingscrew
Retainingscrew
PRH 20 2.0
CODE LENGTH
PRH 30 3.0
Laboratoryscrew
Laboratoryscrew
PL 1405 short
CODE
PTMA 13-1 long
10 N.cm
CODE DIAM. LENGTH
3.3 0.8
3.3 1.5
3.3 2.5
3.3 3.5
3.3 4.5
3.3 5.5
4.5 0.8
4.5 1.5
4.5 2.5
4.5 3.5
4.5 4.5
4.5 5.5
CODE DIAM. LENGTH4.8 0.8
4.8 1.5
4.8 2.5
4.8 3.5
4.8 4.5
4.8 5.5
Angled multi-unit abutment*
Straight multi-unit abutment
DIAM. LENGTH3.5 0.8
3.5 1.5
3.5 2.5
3.5 3.5
3.5 4.5
CODE
CODE
CODE CODE
CODE
CODECODE CODE
CODE
For angled multi-unit
For straight multi-unit
CODE
Cobalt-chrome
Plastic
CODE
CODE
Healing cap
Micro multi-unit Abutment
CODE DIAM. LENGTH4.8 1.5
4.8 2.5
4.8 3.5
4.8 1.5
4.8 2.5
4.8 3.5
ANG.17º
17º
17º
30º
30º
30º
Abutment protector
Open tray transfer
Analog
CODE
PPMM 33
Abutment protector
Open tray transfer
Closed tray transfer
Polishing protector
Polishing protector
Temporarytitanium cylinder
Temporary titanium cylinder
Analog
Calcinable Co-Cr cylinder
Calcinable Co-Cr cylinder
CPM 4800-2 For angled multi-unit
CPM 4800-3 For straight multi-unit
CLEM 4800-2 Cobalt-chrome/For angled multi-unit
CLEM 4800-3 Cobalt-chrome/For straight multi-unit
15 N.cm
20 N.cm
10 N.cm
10 N.cm
10 N.cm
10 N.cm
CODE
CODE10 N.cm
20 N.cm
* Use hexagonal driver 0.9 mm
PRIM
E
CODE DIAM. LENGTH
3.5 8.5
3.5 10.0
3.5 11.5
3.5 13.0
3.5 15.0
4.3 8.5
4.3 10.0
4.3 11.5
4.3 13.0
4.3 15.0
5.0 8.5
5.0 10.0
5.0 11.5
5.0 13.0
5.0 15.0
All measurements in mm
UCM 3585N
UCM 3510N
UCM 3511N
UCM 3513N
UCM 3515N
UCM 4385N
UCM 4310N
UCM 4311N
UCM 4313N
UCM 4315N
UCM 5085N
UCM 5010N
UCM 5011N
UCM 5013N
UCM 5015N
CIMU 3308
CIMU 3315
CIMU 3325
CIMU 3335
CIMU 3345
CIMU 3355
CIMU 4508
CIMU 4515
CIMU 4525
CIMU 4535
CIMU 4545
CIMU 4555
MAMU 4808
MAMU 4815
MAMU 4825
MAMU 4835
MAMU 4845
MAMU 4855
MAMA 1715
MAMA 1725
MAMA 1735
MAMA 3015
MAMA 3025
MAMA 3035
CODEMMAM 3308
MMAM 3315
MMAM 3325
MMAM 3335
MMAM 3345
PMM 33 TMM 33 AMMA 33
TMFM 4800
ANMA 4800
TMAM 4800
P MA 4855
PTM 4800-2
PTM 4800-3
PPM 01
CPMT 33
CPMC 33
CPMM 33
PTMMA 14
PRH 3035
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
UNITITE PRIMEMULTI-UNIT ABUTMENTSMULTIPLE SCREW RETAINED RESTORATIONS
16 17
Overdenturebar
13mmØ 1.95mm
Ø 4.2mm
CODE DIAM. LENGTH
MAMU 4808 4.8 0.8
MAMU 4815 4.8 1.5
MAMU 4825 4.8 2.5
MAMU 4835 4.8 3.5
MAMU 4845 4.8 4.5
MAMU 4855 4.8 5.5
DIAM. CODE LENGTH
CIMU 3308 3.3 0.8
CIMU 3315 3.3 1.5
CIMU 3325 3.3 2.5
CIMU 3335 3.3 3.5
CIMU 3345 3.3 4.5
CIMU 3355 3.3 5.5
CIMU 4508 4.5 0.8
CIMU 4515 4.5 1.5
CIMU 4525 4.5 2.5
CIMU 4535 4.5 3.5
CIMU 4545 4.5 4.5
CIMU 4555 4.5 5.5
CODE
PMA 4855
CODE
TMFM 4800
CODE
ANMA 4800
CODE
FO 01
CODE
CLIPP
CODE
TMAM 4800Healing cap
Straight multi-unitabutment
All measurements in mm
CODE DIAM. LENGTH
3.5 8.5
3.5 10.0
3.5 11.5
3.5 13.0
3.5 15.0
4.3 8.5
4.3 10.0
4.3 11.5
4.3 13.0
4.3 15.0
5.0 8.5
5.0 10.0
5.0 11.5
5.0 13.0
5.0 15.0
UCM 3585N
UCM 3510N
UCM 3511N
UCM 3513N
UCM 3515N
UCM 4385N
UCM 4310N
UCM 4311N
UCM 4313N
UCM 4315N
UCM 5085N
UCM 5010N
UCM 5011N
UCM 5013N
UCM 5015N
Abutmentprotector
Calcinable Co-Cr cylinder
Open traytransfer
Plastic clip
Angled multi-unit abutment*
Closed traytransfer
Analog
CODE
CLEM 4800-2 Cobalt-chromeFor angled multi-unit
CLEM 4800-3 Cobalt-chromeFor straight multi-unit
CPM 4800-2 PlasticFor angled multi-unit
CPM 4800-3 PlasticFor straight multi-unit
45mm
Ø 2.5mm
CODE DIAM. LENGTH
4.8 1.5
4.8 2.5
4.8 3.5
4.8 1.5
4.8 2.5
MAMA 1715
MAMA 1725
MAMA 1735
MAMA 3015
MAMA 30254.8 3.5
ANG.
17°
17°
17°
30°
30°30°MAMA 3035
15 N.cm
10 N.cm
20 N.cm
* Use hexagonal driver 0.9 mm
PRIM
E
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
UNITITE PRIMEOVERDENTURE SOLUTIONSMULTI-UNIT + BAR-CLIP RESTORATIONS
18 19
UNITITE PRIMEOVERDENTURE SOLUTIONSO´RING ATTACHMENT
Open traytransfer
Abutment O’Ring
O’Ring attachment torque driver
O’Ring attachment hand driver
O’Ring insert hand driver
O’Ring removal hand driver
All measurements in mm
DIAM. LENGTH
3.5 8.5
3.5 10.0
3.5 11.5
3.5 13.0
3.5 15.0
4.3 8.5
4.3 10.0
4.3 11.5
4.3 13.0
4.3 15.0
5.0 8.5
5.0 10.0
5.0 11.5
5.0 13.0
5.0 15.0
CODE
UCM 3585N
UCM 3510N
UCM 3511N
UCM 3513N
UCM 3515N
UCM 4385N
UCM 4310N
UCM 4311N
UCM 4313N
UCM 4315N
UCM 5085N
UCM 5010N
UCM 5011N
UCM 5013N
UCM 5015N
Healing cap Analog
CODE DIAM. LENGTH
CIMU 3308 3.3 0.8
CIMU 3315 3.3 1.5
CIMU 3325 3.3 2.5
CIMU 3335 3.3 3.5
CIMU 3345 3.3 4.5
CIMU 3355 3.3 5.5
CIMU 4508 4.5 0.8
CIMU 4515 4.5 1.5
CIMU 4525 4.5 2.5
CIMU 4535 4.5 3.5
CIMU 4545 4.5 4.5
CIMU 4555 4.5 5.5
CODE
TMAMU
CODE
ANMU
CODE DIAM. LENGTH
AOM 4815 4.0 1.5
AOM 4825 4.0 2.5
AOM 4835 4.0 3.5
AOM 4845 4.0 4.5
CODECCAO 20
CCAO 24
CODECDAO 20
CDAO 24
CODEMOR
CODEROR
Titanium cap+O’Ring O’Ring Directional
rings
CODE
AFROM
CODE
OCAN
CODE
POS01 0º White
POS02 7º Yellow
POS03 14º Blue
Closed tray transfer
CODE
TMFMU
20 N.cm
PRIM
E
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
*Coming soon. Check availability with your distributer.
20 21
Analog
Temporaryacrylic Cylinder
CODE DIAM. LENGTH
2.9 10.0
2.9 11.5
2.9 13.0
CODE DIAM. LENGTH
3.3 4.03.3 6.0
CODE DIAM. LENGTH
ASIT 3340 3.3 4.0
ASIT 3360 3.3 6.0
CODE DIAM. LENGTH
3.3 4.0
3.3 6.0
Healing cap
CODE DIAM. LENGTH
3.3 1.5
3.3 2.5
3.3 3.5
3.3 4.5
CODE DIAM. TRANSMUCOSAL LENGTH
CEMENTATION LENGTH
3.3 0.8 4.0
3.3 1.5 4.0
3.3 2.5 4.0
3.3 3.5 4.0
3.3 4.5 4.0
3.3 5.5 4.0
3.3 0.8 6.0
3.3 1.5 6.0
3.3 2.5 6.0
3.3 3.5 6.0
3.3 4.5 6.0
3.3 5.5 6.0
Straight universal abutment
Calcinablepolyacetal cylinder
Suitable for late loading: As from 60 days.
Includes cover screw of 2.0 mm.
Recommended 1.5 mm infra-bone installation.
Indicated for all type of bones.
Internal angle of 3°.
All measurements in mm
* In bone types I and II the bone tap is required to not exceed the recommended torque, and ensure the correct healing process.
Maximum Torque: 45 N.cm.
Speed of the initial drills: 1,200 rpm.
Speed of the drill 2.7mm: 800 rpm.
Speed of the bone tap: 20 rpm*.
Insertion speed: 20 to 40 rpm.
15 N.cm
PolyacetalImpression Transfer
SLIM
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
UCMS 2910N
UCMS 2911N
UCMS 2913N
CIMUS 3315
CIMUS 3325
CIMUS 3335
CIMUS 3345
AISITS 334008
AISITS 334015
AISITS 334025
AISITS 334035
AISITS 334045
AISITS 334055
AISITS 336008
AISITS 336015
AISITS 336025
AISITS 336035
AISITS 336045
AISITS 336055
TSIT 3340TSIT 3360
CPSIT 3340
CPSIT 3360
CODE DIAM. LENGTH
3.3 4.0
3.3 6.0
CCSIT 3340
CCSIT 3360
UNITITE SLIMUNIVERSAL ABUTMENT - PRE-MADE POSTSCEMENTED RETAINED RESTORATIONS
22 23
CODE DIAM. TRANSMUCOSAL LENGTH
3.5 1.5
3.5 2.5
3.5 3.5
CODE
PMM 33
CODE DIAM. LENGTH
CIMUS 3315 3.3 1.5
CIMUS 3325 3.3 2.5
CIMUS 3335 3.3 3.5
CIMUS 3345 3.3 4.5
CODE CODE
CODE
CPMC 33
CODE
PRH 3035 1.4
CODE
1.4
Abutment protector
Open traytransfer
PolishingprotectorAnalog
Calcinable Co-Cr cylinder
Laboratoryscrew
Retaining screw
LENGTH
LENGTH
CODE
PPMM 33
15 N.cm
10 N.cm
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
10 N.cm
10 N.cm
CPMM 33 Cobalt-chrome
SLIM
Healing cap Micro multi-unit Abutment
CODE DIAM. LENGTH
2.9 10.0
2.9 11.5
2.9 13.0
All measurements in mm
UCMS 2910N
UCMS 2911N
UCMS 2913N
MMAMS 3315
MMAMS 3325
MMAMS 3335
TMM 33 AMMA 33
CODE
Temporarytitanium cylinder
CPMT 33
PTMMA 14
UNITITE SLIMMICRO MULTI-UNIT ABUTMENTMULTIPLE SCREW RETAINED RESTORATIONS
24 25
Temporaryacrylic cylinder
Calcinablepolyacetal cylinder
Includes cover screw of 0.0 mm.
Recommended bone level installation.
Indicated for all type of bones
Internal angle of 4°
All measurements in mm
Polyacetal Impression Transfer Healing cap Straight universal abutment Analog
CODE DIAM. LENGTH
4.0 5.0
4.0 6.0
4.0 7.0
5.0 5.0
5.0 6.0
5.0 7.0
6.0 5.0
6.0 6.0
6.0 7.0
CODE DIAM. LENGTH
4.0 2.0
4.0 4.0
4.0 6.0
UCMC 4005N
UCMC 4006N
UCMC 4007N
UCMC 5005N
UCMC 5006N
UCMC 5007N
UCMC 6005N
UCMC 6006N
UCMC 6007N
Suitable for late loading: As from 60 days.
* In bone types I and II the bone tap is required to not exceed the recommended torque and ensure the correct healing process.
4.5 1.0 4.0
4.5 2.0 4.0
4.5 3.0 4.0
4.5 4.0 4.0
4.5 5.0 4.0
4.5 1.0 6.0
4.5 2.0 6.0
4.5 3.0 6.0
4.5 4.0 6.0
4.5 5.0 6.0
CODE DIAM. TRANSMUCOSAL LENGTH
CEMENTATION LENGTH
AIMC 45401
AIMC 45402
AIMC 45403
AIMC 45404
AIMC 45405
AIMC 45601
AIMC 45602
AIMC 45603
AIMC 45604
AIMC 45605
CODE DIAM. LENGTH
TSIT 4540 4.5 4.0
TSIT 4560 4.5 6.0
CODE DIAM. LENGTH
4.5 4.0
4.5 6.0
CODE DIAM. LENGTH
CCSIT 4540 4.5 4.0
CCSIT 4560 4.5 6.0
CODE DIAM. LENGTH
4.5 4.0
4.5 6.0
ASIT 4540
ASIT 4560
Speed of the initial drills: 1,200 rpm.
Speed of the drills 2.7 to 5.8mm: 800 rpm.
Speed of the bone tap: 20 rpm*.
Insertion speed: 20 to 40 rpm.
Maximum Torque: 60 N.cm.
20 N.cm
COM
PACT
CIC 4002
CIC 4004
CIC 4006
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
CPSIT 4540
CPSIT 4560
UNITITE COMPACTUNIVERSAL ABUTMENT - PRE-MADE POSTSCEMENTED RETAINED RESTORATIONS
26 27
All measurements in mm
Laboratory screw
Retainingscrew
PL 1405 Short
PTMA 13-1 Long
CODE
Healing cap Multi-unitAbutment
Analog
CODE DIAM. LENGTH
4.0 5.0
4.0 6.0
4.0 7.0
5.0 5.0
5.0 6.0
5.0 7.0
6.0 5.0
6.0 6.0
6.0 7.0
CODE DIAM.
CIC 4002 4.0
CIC 4004 4.0
CIC 4006 4.0
UCMC 4005N
UCMC 4006N
UCMC 4007N
UCMC 5005N
UCMC 5006N
UCMC 5007N
UCMC 6005N
UCMC 6006N
UCMC 6007N
CODE
CODE
TMAM 4800
CODE
TMFM 4800
2.0
4.0
6.0
LENGTH
MAC 4801 4.8 1.0
MAC 4802 4.8 2.0
MAC 4803 4.8 3.0
MAC 4804 4.8 4.0
MAC 4805 4.8 5.0
CODE DIAM. TRANSMUCOSAL LENGTH
Abutmentprotector
Open tray transfer
Closed traytransfer
CODECODEANMA 4800
CODE
CPM 4800-3 For straight multi-unit
CLEM 4800-3 Cobalt-chrome/For straight multi-unit
Temporarytitanium cylinder
CODE
PTM 4800 -3 For straight multi-unit
Calcinable Co-Cr cylinder
Polishing protector
CODE LENGTH
PRH 30 3.0
10 N.cm
10 N.cm
10 N.cm
COM
PACT
20 N.cm
PMA 4855
Hex Screw
Anti-Rotational Component
Squared Screw
Abutment Screw
Rotational Component
PPM 01
UNITITE COMPACTMULTI-UNIT ABUTMENTMULTIPLE SCREW RETAINED RESTORATIONS
28 29
DRILLING SEQUENCE GUIDE TECHNICAL INFORMATION
Unitite Compact
Unitite Prime
PLAT. (mm)
1.200 RPM 800 RPM 20 RPM
FRLD 2005
FHCD 2015
FUM 2915
FUM 3515
FUM 4315
FUM 5015
CMRU 35
CMRU 43
CMRU 50
3.5 ● ● ● ● ●
4.3 ● ● ● ● ● ●
5.0 ● ● ● ● ● ● ●
Unitite Slim
PLAT. (mm)
1.200 RPM 800 RPM 20 RPM
FRLD 2005 FHCD 2015 FUM 2915 CMRU 29
2.9 ● ● ● ●
Unitite Compact
PLAT. mm )
1.200 RPM 800 RPM 20 RPM
FRLD 2005
FHCD 2015
FUM 2915
FUM 3515
FHCD 3215
FHCD 4215
FHCD 5215
CMRUC 40
CMRUC 50
CMRUC 60
4.0 ● ● ● ● ● ●
5.0 ● ● ● ● ● ● ●
6.0 ● ● ● ● ● ● ● ●
(
2.50 11.5°
3.50
2.50 11.5°
4.30
2.50 11.5°
5
8.5mm10mm
11.5mm13mm15mm
1.8 2.3 3
UCM 35xxN UCM 43xxN UCM 50xxN
Hex. 2
Hex. 2
Hex. 2
3.50
4.30
5
UCMS 29xxN
3°
2
2.90
10mm11.5mm13mm
2.4
Qua
d. 1,3
0
2,90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
3° 2
2,90
10mm11,5mm13mm
2,4
UCMS 29xxN
Quad
. 1.30
2.90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
2.50 4°
4
2.50 4°
5
2.50 4°
6
5mm6mm7mm
UCMC 40xxN UCMC 50xxN UCMC 60xxN
4 5 6
Hex. 2 Hex. 2 Hex. 2
2.50 11.5°
3.50
2.50 11.5°
4.30
2.50 11.5
° 5
8.5mm
10mm
11.5mm
13mm
15mm
1.8 2.3
3
UCM
35xxNU
CM 43xxN
UCM
50xxN
Hex. 2
Hex. 2
Hex. 2
3.50
4.30
5
UCM
S 29xxN
3° 2
2.90
10mm
11.5mm
13mm
2.4
Quad. 1,30
2,90
03/01/2017
Un
itite Slim8:1
Código:
Escala:
Data:
mm
Unidade
3° 2
2,90
10mm
11,5mm
13mm
2,4
UCM
S 29xxN
Quad. 1.30
2.90
03/01/2017
Un
itite Slim8:1
Código:
Escala:
Data:
mm
Unidade
2.50 4° 4
2.50 4° 5
2.50 4° 6
5mm
6mm
7mm
UCM
C 40xxNU
CMC 50xxN
UCM
C 60xxN
4 5
6
Hex. 2 Hex. 2
Hex. 2
2.50 11.5°
3.50
2.50 11.5°
4.30
2.50 11.5°
5
8.5mm10mm
11.5mm13mm15mm
1.8 2.3 3
UCM 35xxN UCM 43xxN UCM 50xxN
Hex. 2
Hex. 2
Hex. 2
3.50
4.30
5
UCMS 29xxN
3°
2
2.90
10mm11.5mm13mm
2.4
Qua
d. 1,3
0
2,90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
3° 2
2,90
10mm11,5mm13mm
2,4
UCMS 29xxN
Quad
. 1.30
2.90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
2.50 4°
4
2.50 4°
5
2.50 4°
6
5mm6mm7mm
UCMC 40xxN UCMC 50xxN UCMC 60xxN
4 5 6
Hex. 2 Hex. 2 Hex. 2
2.50 11.5°
3.50
2.50 11.5°
4.30
2.50 11.5°
5
8.5mm10mm
11.5mm13mm15mm
1.8 2.3 3
UCM 35xxN UCM 43xxN UCM 50xxN
Hex. 2
Hex. 2
Hex. 2
3.50
4.30
5
UCMS 29xxN
3°
2
2.90
10mm11.5mm13mm
2.4
Qua
d. 1,3
0
2,90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
3° 2
2,90
10mm11,5mm13mm
2,4
UCMS 29xxN
Quad
. 1.30
2.90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
2.50 4°
4
2.50 4°
5
2.50 4°
6
5mm6mm7mm
UCMC 40xxN UCMC 50xxN UCMC 60xxN
4 5 6
Hex. 2 Hex. 2 Hex. 2
2.50 11.5°
3.50
2.50 11.5°
4.30
2.50 11.5°
5
8.5mm10mm
11.5mm13mm15mm
1.8 2.3 3
UCM 35xxN UCM 43xxN UCM 50xxN
Hex. 2
Hex. 2
Hex. 2
3.50
4.30
5
UCMS 29xxN
3°
2
2.90
10mm11.5mm13mm
2.4
Qua
d. 1,3
0
2,90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
3° 2
2,90
10mm11,5mm13mm
2,4
UCMS 29xxN
Quad
. 1.30
2.90
03/01/2017
Unitite Slim 8:1Código: Escala:
Data:
mmUnidade
2.50 4°
4
2.50 4°
5
2.50 4°
6
5mm6mm7mm
UCMC 40xxN UCMC 50xxN UCMC 60xxN
4 5 6
Hex. 2 Hex. 2 Hex. 2
Unitite Prime Unitite Slim
For all implants, in bone types I and II the bone tap is required to not exceed the recommended torque and ensure the correct healing process.
Unitite Prime
PLAT. (mm)
1.200 RPM 800 RPM 20 RPM
FRLD 2005
FHCD 2015
FUM 2915
FUM 3515
FUM 4315
FUM 5015
CMRU 35
CMRU 43
CMRU 50
3.5 ● ● ● ● ●
4.3 ● ● ● ● ● ●
5.0 ● ● ● ● ● ● ●
Unitite Slim
PLAT. (mm)
1.200 RPM 800 RPM 20 RPM
FRLD 2005 FHCD 2015 FUM 2915 CMRU 29
2.9 ● ● ● ●
Unitite Compact
PLAT. mm )
1.200 RPM 800 RPM 20 RPM
FRLD 2005
FHCD 2015
FUM 2915
FUM 3515
FHCD 3215
FHCD 4215
FHCD 5215
CMRUC 40
CMRUC 50
CMRUC 60
4.0 ● ● ● ● ● ●
5.0 ● ● ● ● ● ● ●
6.0 ● ● ● ● ● ● ● ●
(
Unitite Prime
PLAT. (mm)
1.200 RPM 800 RPM 20 RPM
FRLD 2005
FHCD 2015
FUM 2915
FUM 3515
FUM 4315
FUM 5015
CMRU 35
CMRU 43
CMRU 50
3.5 ● ● ● ● ●
4.3 ● ● ● ● ● ●
5.0 ● ● ● ● ● ● ●
Unitite Slim
PLAT. (mm)
1.200 RPM 800 RPM 20 RPM
FRLD 2005 FHCD 2015 FUM 2915 CMRU 29
2.9 ● ● ● ●
Unitite Compact
PLAT. mm )
1.200 RPM 800 RPM 20 RPM
FRLD 2005
FHCD 2015
FUM 2915
FUM 3515
FHCD 3215
FHCD 4215
FHCD 5215
CMRUC 40
CMRUC 50
CMRUC 60
4.0 ● ● ● ● ● ●
5.0 ● ● ● ● ● ● ●
6.0 ● ● ● ● ● ● ● ●
(
30 31
ANN WENNERBERGWHAT THE SPECIALISTS SAY
DDS/PhD and Director of the Department of Dental Prosthesis at the Malmö University, Sweden. Specia-lized in Implant Surface and author of more than 220 scientific articles published in renowned magazines on this subject.
“Our research group has worked with the HAnano®
surface for over 10 years. Until now this research has resulted in two doctoral theses and another one is in progress. Our experimental results in 17 in vivo studies, mostly on rabbits, usually shows an improved bone response for the titanium with the HAnano® surface and PEEK implants when compared with implants without this surface.”
STUDIES
FÁBIO BEZERRAWHAT THE SPECIALISTS SAY
"Surface coating HAnano®, used in the Unitite implant, and 20 nanometers thick, homogeneously coating the en-tire surface, significantly increases surface energy, hy-drophilicity and scar response in the early stages of the Osseointegration process. The positive impact of its bio-availability has been demonstrated by different advan-ced methods of research, such as signal transduction and atomic force microscopy. Higher protein adsorption, as-sociated to a statistically significant presence of proteins related to the bone healing process in the presence of a biological catalyst for mineralization, make this surface one of the most advanced in the implants global market.”
A Graduate of Bauru School of Dentistry - USPSpecialist in Periodontics, Bauru School of Dentistry - USPSpecialist in Implantology by INEPO - SPMaster in Implantology by UNIP - São PauloDoctor in Biotechnology by IBB - UNESP
STUDIES
For original titles of the articles mentioned herein, please refer to the Scientific Publications page.
2
3
13
12
11
Functional evaluation of implants by bone mineralization in vitro.Lima JHC; Tanaka MN; Bezerra FJ; Maia VTG; Robbs PCMRev. bras. odontol., Rio de Janeiro, v. 72, n. 1/2, p. 92-5, jan./jun. 2015
Titanium-based dental implants favor cell-signaling pathway involved in the survival and proliferation of os-teoblasts.Bezerra FJ, Rossi MC, Fernandes CJC, Nascimento A, Ferreira MR, Zambuzzi WFInnov Implant J, Biomater Esthet. 2014;9(2/3):8-12
Microtomographic evaluation of a new nanometric hydroxyapatite covered implant surface. In vivo study in diabetic rats.Scombatti de Souza S, Oliveira P, Borges C, Reino D, Novaes Jr A, Taba Jr M, Bezerra FJ.Clin. Oral Impl. Res. 27 (Suppl. 13), 2016
Evaluation of a new nanometric hydroxyapatite covered implant surface. In vivo study in diabetic rats analy-sing osteogenesis gene expression.Oliveira P, Scombatti de Souza S, Sales M, Novaes Jr A, Palioto D, Messora M, Santos F, Bezerra FJ.Clin. Oral Impl. Res. 27 (Suppl. 13), 2016
Nano hydroxyapatite-blasted titanium surface affects pre-osteoblast morphology by modulating critical intra-cellular pathways.Bezerra FJ, Ferreira MR, Fontes GN, da Costa Fernandes C Jr; Andia DC, Cruz NC, da Silva RA; Zambuzzi WF. Biotechnol Bioeng. 2017 Apr 12
45
46
37
38
36
Genetic Responses to Nanostructured Calcium-phosphate-coated Implants.Jimbo R, Xue Y, Hayashi M, Schwartz-Filho HO, Andersson M, Mustafa K, Wennerberg A.J DENT RES published online 20 September 2011
Histological and three-dimensional evaluation of osseointegration to nanostructured calcium phosphate-coa-ted implants.Jimbo R, Coelho PG, Vandeweghe S, Humberto Osvaldo Schwartz-Filho HO, Hayashi M, Ono D, Andersson M, Wennerberg A.Acta Biomater. 2011 Dec;7(12):4229-34.
Nano hydroxyapatite-coated implants improve bone nanomechanical properties.Jimbo R, Coelho PG, Bryington M, Baldassarri M, Tovar N, Currie F, Hayashi M, Janal MN, Andersson M, Ono D, Vandeweghe S, Wennerberg A. J Dent Res. 2012;91(12):1172-7
The biological response to three different nanostructures applied on smooth implant surfaces.Jimbo R, Sotres J, Johansson C, Breding K, Currie F, Wennerberg A. Clin Oral Implants Res. 2012;23(6):706-12
The effect of chemical and nanotopographical modifications on the early stages of osseointegration.Meirelles L, Currie F, Jacobsson M, Albrektsson T, Wennerberg A. Int J Oral Maxillofac Implants. 2008 Jul-Aug;23(4):641-7
32 33
CTO of Promimic, Co-inventor of the HAnano® surface,PhD in Materials and Chemical Surfaces by the ChalmersUniversity in Gothenburg, Sweden, and author of severalstudies in the area of nanomaterials.
“The HAnano® surface is an ultrathin layer of synthetic bone on the surface of the implant. Each crystal of syn-thetic bone is extremely small, 10 to 14 nm in length and about 5nm in thickness. What makes these crystals so special is that they have the same size and shape as those found in human bone and are recognized by the bone cells, as well as by the bone tissue, which activates the catalyzer and starts a huge process of building bone around the implant. This effect has been proven in more than 20 pre-clinical studies with the best researchers in the world in the area of implants.”
PER KJELLIN WHAT THE SPECIALISTS SAY
STUDIES
Researcher in the Bme - KULeuven, Belgium. Post-PhD inBiomechanics by the FEMEC/UFU and Researcher in the Bme- KULeuven, Belgium. PhD in Periodontics/Dental Implant -FOAr/UNESP - Araraquara, Brazil. Master in Oral Rehabilitation- FOUFU - Uberlândia, Brazil.
"UNITITE implants have made the results of current major clinical demands more predictable, such as shortening the time between implant installation and final patient reha-bilitation, maintaining peri-implant bone height, which has a large impact on long-term aesthetic predictability and the rehabilitation of areas with poor bone availability in an efficient and minimally invasive way, in many cases avoiding the need for bone grafts. I am very flattered to have participated actively in this project. "
ROBERTO PESSOA WHAT THE SPECIALISTS SAY
STUDIES
1
4
5
7
Nano hydroxyapatite structures influence early bone formation.Meirelles L, Arvidsson A, Andersson M, Kjellin P, Albrektsson T, Wennerberg A. J Biomed Mater Res A. 2008 Nov;87(2):299-307
Bone reaction to nano hydroxyapatite modified titanium implants placed in a gap-healing model.Meirelles L, Albrektsson T, Kjellin P, Arvidsson A, Franke-Stenport V, Andersson M, Currie F, Wennerberg A. J Biomed Mater Res A. 2008 Dec 1;87(3):624-31
Effect of hydroxyapatite and titania nanostructures on early in vivo bone response.Meirelles L, Melin L, Peltola T, Kjellin P, Kangasniemi I, Currie F, Andersson M, Albrektsson T, Wennerberg A. Clin Implant Dent Relat Res. 2008 Dec;10(4):245-54
Evaluation of bone healing on sandblasted and acid etched implants coated with nanocrystalline hydroxyapa-tite: an in vivo study in rabbit femur.Svanborg LM, Meirelles L, Franke-Stenport V, Kjellin P, Currie F, Andersson M, Wennerberg A.International Journal of Dentistry 2014;2014:197581. Epub 2014 Mar 2
Bone Remodeling Around Implants with External Hexagon and Morse-Taper Connections: A Randomized, Con-trolled, Split-Mouth, ClinicalTrial.Pessoa RS, Sousa RM, Pereira LM, Neves FD, Bezerra FJ, Jaecques SV, Sloten JV, Quirynen M, Teughels W, Spin-Neto R.Clin Implant Dent Relat Res. 2017 Feb;19(1):97-110
Influence of implant design on the biomechanical environment of immediately placed implants: computed to-mography-based nonlinear three-dimensional finite element analysis.Pessoa RS, Coelho PG, Muraru L, Marcantonio Jr E, Vaz LG, Sloten JV, Jaecques SV. Int J Oral Maxillofac Implants. 2011 Nov-Dec;26(6):1279-87
Biomechanical evaluation of platform switching: different mismatch sizes, connection types, and implant pro-tocols.Pessoa RS, Bezerra FJ, Sousa RM, Vander Sloten J, Casati MZ, Jaecques SV.J Periodontol. 2014 Sep;85(9):1161-71
Influence of Connection Types and Implant Number on the Biomechanical Behavior of Mandibular Full-Arch Rehabilitation.Sousa RM, Simamoto-Junior PC, Fernandes-Neto AJ, Sloten JV, Jaecques SV, Pessoa RS. Int J Oral Maxillofac Implants. 2016 Jul-Aug;31(4):750-60
Influence of implant connection type on the biomechanical environment of immediately placed implants - CT--based nonlinear, three-dimensional finite element analysis.Pessoa RS, Muraru L, Júnior EM, Vaz LG, Sloten JV, Duyck J, Jaecques SV.Clin Implant Dent Relat Res. 2010 Sep;12(3):219-34.
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For original titles of the articles mentioned herein, please refer to the Scientific Publications page.
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SCIENTIFIC PUBLICATIONSNano hydroxyapatite structures influence early bone formation.Meirelles L, Arvidsson A, Andersson M, Kjellin P, Albrektsson T, Wennerberg A. J Biomed Mater Res A. 2008 Nov;87(2):299-307
The effect of chemical and nanotopographical modifications on the early stages of osseointegration. Meirelles L, Currie F, Jacobsson M, Albrektsson T, Wennerberg A. Int J Oral Maxillofac Implants. 2008 Jul-Aug;23(4):641-7
Nano hydroxyapatite-coated implants improve bone nanomechanical properties. Jimbo R, Coelho PG, Bryington M, Baldassarri M, Tovar N, Currie F, Hayashi M, Janal MN, Andersson M, Ono D, Vandeweghe S, Wennerberg A. J Dent Res. 2012;91(12):1172-7
Effect of hydroxyapatite and titania Nanostructures on early in vivo bone response.Meirelles L, Melin L, Peltola T, Kjellin P, Kangasniemi I, Currie F, Andersson M, Albrektsson T, Wennerberg A. Clin Implant Dent Relat Res. 2008 Dec;10(4):245-54
Evaluation of bone healing on sandblasted and acid etched implants coated with nanocrystalline hydroxyapa-tite: an in vivo study in rabbit femur. Melin Svanborg L, Meirelles L, Franke-Stenport V, Kjellin P, Currie F, Andersson M, Wennerberg A.International Journal of Dentistry 2014;2014:197581.
Classification of osseointegrated implant surfaces: materials, chemistry and topography. Donhan Ehrenfest DM, Coelho PG, Kang BS, Sul YT, Albrektsson T. Trends Biotechnol. 2010 Apr;28(4):198-206
Bone reaction to nano hydroxyapatite modified titanium implants placed in a gap-healing model.Meirelles L, Albrektsson T, Kjellin P, Arvidsson A, Franke-Stenport V, Andersson M, Currie F, Wennerberg A. J Biomed Mater Res A. 2008 Dec 1;87(3):624-31
Nanohydroxyapatite-coated PEEK implants: a pilot study in rabbit bone. Barkarmo S, Wennerberg A, Hoffman M, Kjellin P, Breding K, Handa P, Stenport V. J Biomed Mater Res A. 2013 Feb;101(2):465-71
An in vitro comparison of possibly bioactive titanium implant surfaces.Göransson A, Arvidsson A, Currie F, Franke-Stenport V, Kjellin P, Mustafa K, Sul YT, Wennerberg A. J Biomed Mater Res A. 2009 Mar 15;88(4):1037-47
Formation of calcium phosphates on titanium implants with four different bioactive surface preparations. An in vitro study.Arvidsson A, Franke-Stenport V, Andersson M, Kjellin P, Sul YT, Wennerberg A. J Mater Sci Mater Med. 2007 Oct;18(10):1945-54.
The biological response to three different nanostructures applied on smooth implant surfaces. Jimbo R, Sotres J, Johansson C, Breding K, Currie F, Wennerberg A. Clin Oral Implants Res. 2012;23(6):706-12
Genetic Responses to nanostructured calcium-phosphate-coated Implants.Jimbo R, Xue Y, Hayashi M, Schwartz-Filho HO, Andersson M, Mustafa K, Wennerberg A.J DENT RES published online 20 September 2011
Histological and three-dimensional evaluation of osseointegration to nanostructured calcium phosphate-coated implants.Jimbo R, Coelho PG, Vandeweghe S, Humberto Osvaldo Schwartz-Filho HO, Hayashi M, Ono D, Andersson M, Wennerberg A.Acta Biomater. 2011 Dec;7(12):4229-34.
Precipitation of calcium phosphate in the presence of albumin on titanium implants with four different possi-bly bioactive surface preparations. An in vitro study. Stenport V , Kjellin P, Andersson M, Currie F, Sul Y-T, Wennerberg A, Arvidsson A.J Mater Sci: Mater Med. 2008;19:3497–505
Nucleation and growth of calcium phosphates in the presence of fibrinogen on titanium implants with four poten-tially bioactive surface preparations. an in vitro study. Arvidsson A, Currie F, Kjellin P, Sul YT, Stenport V. J Mater Sci Mater Med. 2009 Sep;20(9):1869-79
Early bone healing and biomechanical fixation of dual acidetched and as-machined implants with healing cham-bers: an experimental study in dogs. Bonfante EA, Granato R, Marin C, Suzuki M, Oliveira SR, Giro G, Coelho PG.Int J Oral Maxillofac Implants. 2011 Jan-Feb;26(1):75-82
Osseointegration: hierarchical designing encompassing the macrometer, micrometer, and nanometer length scales. Coelho PG, Jimbo R, Tovar N, Bonfante EA. Dent Mater. 2015;31(1):37-52
Are insertion torque and early osseointegration proportional? A histologic evaluation. Baires-Campos FE, Jimbo R, Bonfante EA, Barbosa DZ, Oliveira MT, Janal MN, Coelho PG. Clin Oral Implants Res. 2015 Nov;26(11):1256-60.
Fracture strength and probability of survival of narrow and extra-narrow dental implants after fatigue testing: In vitro and in silico analysis. Bordin D, Bergamo ETP, Fardin VP, Coelho PG, Bonfante EA.J Mech Behav Biomed Mater. 2017 Jul;71:244-249
Drilling dimension effects in early stages of osseointegration and implant stability in a canine model. Baires-Campos FEB, Jimbo R, Bonfante EA, Oliveira MTF, Moura C, Barbosa DZ, Coelho PG.Med Oral Patol Oral Cir Bucal. 2015 Jul 1;20(4):e471-9
Osseointegration of metallic devices: current trends based on implant hardware design. Coelho PG, Jimbo R. Archives of biochemistry and biophysics. 2014;561:99-108
Buccal and lingual bone level alterations after immediate implantation of four implant surfaces: a study in dogs. Bonfante EA, Janal MN, Granato R, Marin C, Suzuki M, Tovar N, Coelho PG. Clin Oral Implants Res. 2013 Dec;24(12):1375-80
Alveolar buccal bone maintenance after immediate implantation with a surgical flap approach: a study in dogs. Coelho PG, Marin C, Granato R, Bonfante EA, Lima CP, Oliveira S, Dohan Ehrenfest DM, Suzuki M. The International Journal of Periodontics & Restorative Dentistry 2011;31:e80–e86
Influence of clinically relevant factors on the immediate biomechanical surrounding for a series of dental im-plant designs. Shunmugasamy VC, Gupta N, Pessoa RS, Janal MN, Coelho PG. J Biomech Eng. 2011;133(3):031005
Basic research methods and current trends of dental implant surfaces.Coelho PG, Granjeiro JM, Romanos GE, Suzuki M, Silva NR, Cardaropoli G, Thompson VP, Lemons JE. J Biomed Mater Res B Appl Biomater. 2009;88(2):579-96
Influence of implant design on the biomechanical environment of immediately placed implants: computed to-mography-based nonlinear three-dimensional finite element analysis. Pessoa RS, Coelho PG, Muraru L, Marcantonio Jr E, Vaz LG, Sloten JV, Jaecques SV. Int J Oral Maxillofac Implants. 2011 Nov-Dec;26(6):1279-87
Fatigue reliability of three single-unit implant-abutment designs. Martins LM, Martins LM, Bonfante EA, Zavanelli RA, Freitas AC Jr, Silva NR, Marotta L, Coelho PG. Implant Dent. 2012 Feb;21(1):67-71
Immediate or early loading of implants with healing chambers and nano-surface: a non-interferential longitudi-nal prospective studyCarregamento funcional imediato ou precoce de implantes com câmara de cicatrização e superfície nanométrica: estudo clínico prospectivo longitudinal.Bezerra FJ, Pessoa RS, Zambuzzi WF.Innov Implant J, Biomater Esthet. 2014;9(2/3):13-7
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SCIENTIFIC PUBLICATIONSInfluence of connection types and implant number on the biomechanical behavior of mandibular full-arch rehabilitation. Sousa RM, Simamoto-Junior PC, Fernandes-Neto AJ, Sloten JV, Jaecques SV, Pessoa RS. Int J Oral Maxillofac Implants. 2016 Jul-Aug;31(4):750-60
Bone remodeling around implants with external hexagon and morse-taper connections: a randomized, control-led, split-mouth, clinical trial.Pessoa RS, Sousa RM, Pereira LM, Neves FD, Bezerra FJ, Jaecques SV, Sloten JV, Quirynen M, Teughels W, Spin-Neto R.Clin Implant Dent Relat Res. 2017 Feb;19(1):97-110
Bone remodeling of implants with external hexagon connection and retention elements at the crestal module under immediate loading – a 1-year longitudinal prospective clinical trial.Remodelação óssea de implantes com conexão hexágono externo e elementos de retenção no módulo da crista sob car-regamento imediato – estudo clínico prospectivo longitudinal de um ano.Pessoa RS, Souza RM, Pereira LM, Neves FD, Jaecques SVN, Sloten JV, Quirynen M, Teughels W, Spin-Neto R. ImplantNews 2015;12(4):E2-E7
Soft and hard tissue maintenance following placement of immediate-loaded implants in the aesthetic zone: a prospective longitudinal clinical trial.Avaliação da estabilidade dos tecidos duros e moles em implantes imediatos com carga imediata em área estética: estudo clínico.Pessoa RS, Sousa RM, Pereira LM, Silva TD, Bezerra FJ, Spin-Neto R. Dental Press Implantol. 2015 Apr-Jun;9(2):100-9
Edentulism impact assessment and rehabilitation mandibular total fixed on implants with immediate loading in patients’ quality of life of elderly.Avaliação do impacto do edentulismo total mandibular e da reabilitação fixa sobre implantes com carga imediata na qualidade de vida de pacientes idosos.Bezerra FJ, Lenharo A, Pessoa RS, Duarte LRS, Granjeiro JM. Rev Dental Press Periodontia Implantol. 2011 jul-set;5(3):101-10
Biomechanical evaluation of platform switching: different mismatch sizes, connection types, and implant protocols.Pessoa RS, Bezerra FJ, Sousa RM, Vander Sloten J, Casati MZ, Jaecques SV.J Periodontol. 2014 Sep;85(9):1161-71
Influence of implant connection type on the biomechanical environment of immediately placed implants - CT--based nonlinear, three-dimensional finite element analysis.Pessoa RS, Muraru L, Júnior EM, Vaz LG, Sloten JV, Duyck J, Jaecques SV.Clin Implant Dent Relat Res. 2010 Sep;12(3):219-34.
Nano hydroxyapatite-blasted titanium surface affects pre-osteoblast morphology by modulating critical intra-cellular pathways.Bezerra FJ, Ferreira MR, Fontes GN, da Costa Fernandes C Jr; Andia DC, Cruz NC, da Silva RA; Zambuzzi WF. Biotechnol Bioeng. 2017 Apr 12
Microtomographic evaluation of a new nanometric hydroxyapatite covered implant surface. In vivo study in diabetic rats.Scombatti de Souza S, Oliveira P, Borges C, Reino D, Novaes Jr A, Taba Jr M, Bezerra FJ.Clin. Oral Impl. Res. 27 (Suppl. 13), 2016
Evaluation of a new nanometric hydroxyapatite covered implant surface. In vivo study in diabetic rats analysing osteogenesis gene expression.Oliveira P, Scombatti de Souza S, Sales M, Novaes Jr A, Palioto D, Messora M, Santos F, Bezerra FJ.Clin. Oral Impl. Res. 27 (Suppl. 13), 2016
Biofilm formation on nanostructured hydroxyapatite-coated titanium.Westas E, Gillstedt M, Lönn-Stensrud J, Bruzell E, Andersson M.Biomed Mater Res A. 2014 Apr;102(4):1063-70
Nanocrystalline hydroxyapatite/titania coatings on titanium improves osteoblast adhesion. Sato M, Aslani A, Sambito MA, Kalkhoran NM, Slamovich EB, Webster TJ.J Biomed Mater Res. 2008;84A:265–72
Topography and surface energy of dental implants: a methodological approach.Barbosa TP, Naves MM, Menezes HHM, Pinto PHC, de Mello JDB, Costa HL. Journal of The Brazilian Society of Mechanical Sciences and Engineering 2017. June 2017, Volume 39, Issue 6, pp 1895–1907
Influence of macro-geometry in the primary stability of implants.Influência da macrogeometria na estabilidade primária dos implantes.Bezerra FJ, Ribeiro EP, Bittencourt S, Lenharo A.Innov Implant J 2010; 5:29-34
Influence of implant geometry on primary stability at diferent bone density.Influência da macrogeometria na estabilidade primária dos implantes em diferentes densidades ósseas.Bezerra FJ, Ribeiro EP, Bittencourt S, Lenharo A. Implant News 2010;7(5):671-6.
A multi-center prospective longitudinal study evaluating the clinical success rates of osseointegrated implants with a new macro-geometry: 6 to 12 months follow-up.Estudo prospectivo longitudinal multicêntrico avaliando o sucesso clínico de uma nova macrogeometria de implantes osseointegráveis: acompanhamento de 06 a 12 meses.Lenharo A, Granjeiro JM, Leão L, Bezerra FJ, Oliva MA. Revista Fluminense de Odontologia 2010; 34: 43-48
Functional evaluation of implants by bone mineralization in vitro.Avaliação funcional de implantes por mineralização óssea in vitro.Lima JHC; Tanaka MN; Bezerra FJ; Maia VTG; Robbs PCMRev. bras. odontol., Rio de Janeiro, v. 72, n. 1/2, p. 92-5, jan./jun. 2015
Titanium-based dental implants favor cell-signaling pathway involved in the survival and proliferation of os-teoblasts.Implantes dentários à base de titânio favorecem via de sinalização celular envolvidas com sobrevivência e proliferação de osteoblastosBezerra FJ, Rossi MC, Fernandes CJC, Nascimento A, Ferreira MR, Zambuzzi WFInnov Implant J, Biomater Esthet. 2014;9(2/3):8-12
Influence of operador experience on primary stability of implants with different geometry: in vitro study.Influência da experiência do operador na estabilidade primária de implantes com diferentes macrogeometrias – estudo in vitro.Bezerra FJ, Ribeiro EDP, Bittencourt S, Lenharo A.IJD, Int. j. dent. 2010, vol.9, n.2, pp. 63-67. ISSN 1806-146X.
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ABOUT US
Established in 2003, S.I.N. Implant System is one of the largest dental implant companies in the global market today, with 700,000 implants sold annually, offering a wide range of pro-ducts and with a strong global presence.
The combination of the latest in cutting-edge technologies with results of scientific investigations conducted alongside the world's leading dentistry universities has led us to produce sim-ple solutions that meet the needs of our customers, simplify processes, leading to a positive and safe experience for both professional and patient.
There are hundreds of publications and in-ternational research studies; in addition to trials conducted in over 40 universities.
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