This document discusses different classifications and types of dental implants. It begins by summarizing common classification systems according to the tissue they are embedded in or rest on, as well as based on their material composition. Specific implant systems are then described in detail such as the IMZ, Innova, Nobel Biocare, and others. Surgical procedures for stage one implant placement are outlined, including the use of guides, drills, taps, and implant insertion. Materials used for implants include metals, ceramics, polymers and composites.
2. INDIAN DENTAL ACADEMY
Leader in continuing dental education
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3. Classification of Implant
According to Leonard. R.Rubin
Classified according to the tissue into which they are
embedded or on which they rest:
Intraosseous implants: Receiving primary support from
within bone
Subperiosteal implants: resting on the bone beneath the
periosteum
Transosseous implants: stabilized by penetrating
through both cortical plates
Transcanal: support from an implant placed through the
tooth root canal into the bone beyond the apex
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4. According to Charles. A.Babbush
There are five main types:
• Mucosal Inserts
• Subperiosteal Implants
• Endodontic Implants
• Endosseous Implants
• Transosteal Implants
According to Dennis C. Smith,
David.F.Williams
• Buried: Metals
Non-Metals
Metals: Magnets placed in the superior aspect of the
body of the mandible and another set placed in the
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lower denture
5. Endodontic Stabilizers: Metal rods cemented into
root canal of a natural tooth and extends beyond apex
into the bone
Non-metals: In ridge augmentation and facial
recountouring procedures using proplast, ceramics
and plastics
Also in ridge maintenance efforts by placing
implants made of carbon into recent extraction site
root sockets
• Semi-Buried:
All true dental implants fall into this category
Metals: Cobalt, Chromium, Molybdenum
Non-metals: Ceramics, Bioglass, Carbons, Plastics
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6. Classification of Implant
Biomaterials
According to Charles A.Babbush, Carl. E. Misch
• Metals and Alloys
• Ceramics and Carbon
• Synthetic Polymers and Composites
Metals and Alloys:
Titanium
Co-Cr-Mo based alloy
Iron-Chromium-Nickel based alloy
Other metals
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10. According to Stephen.D.Cook; Jeanette. E.Dalton
(Based on Tissue Response and Systemic
Toxicity)
Biotolerant
Bioactive
Bioinert
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11. Implant Systems
IMZ Dental Implant Systems
Innova Endopore Implant System
Nobel Biocare and 3i Systems
Sulzer-Calcitek Implant System
Friatec and Frialit
Oratronics Spiral
Implant Innovations incorporated
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13. It consists of a cylindrical, endosseous
implant; a highly polished transmucosal
implant extension (TIE), and a viscoelastic
intramobile element (IME)
This has been in use since 1978
It is made of commercially pure titanium
The outer surface is titanium plasmasprayed with an electric arc, which gives
rough texture and a large surface area
Apical end of implant contains vent for
bone ingrowth
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14. They are available in 3.3, 4.0 and 4.25 mm
diameter and in lengths of 8,11,13,15,17, and
19 mm
The Transmucosal Implant Extension (TIE) is
an highly polished titanium sleeve that sits on
top of the implant and extends up through the
soft tissue
Designed to be easily cleaned in situ by patient
and can be removed by dentist for extraoral
cleaning
The Intramobile Element (IME) is made up of
polyoxymethylene and provides a resilient
connection between the implant and prosthesis
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15. 4 mm implants in lengths 8,11,13
and 15 mm. placement head
assemble, titanium healing screw,
second-phase sealing screw and
TIE, IME and TIE,
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16. They are developed by Interpore
International, Irvine
Indicated in totally edentulous, partial
edentulous, class I and II and single tooth
edentulous space
IME is designed to minimize stress
concentrations, by absorbing and
distributing occlusal surfaces
Abutments systems are two: the
conventional TIE and IME ; the intramobile
connector (IMC)
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21. For partially edentulous patients
Implant is rigidly connected to the natural
tooth using an extracoronal screwstabilized attachment
Indicated for maxillary and mandibular
posterior edentulous situations
It distributes load between the implant and
the natural abutment
Possible if an semiprecision or telescopic
attachment is used to connect teeth to
implants
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24. Single-tooth abutment has been designed
for use with IMZ implant
In anterior regions of the mouth
This titanium abutment is a two-piece
insert
Transmucosal section tightened against
top of the implant body
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26.
Prefabricated
ceramicor post and
ring on the right
designed so that
when seated into
abutment on left, post
fits precisely over
coronal aspect of
abutment
crown secured by
using cement
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27. Noble Biocare and 3i Systems
Both systems are similar
Packaged differently: glass tube and blister
pack
Various coating like hydroxylapatite and
titanium plasma spray are available
Diameters– 3.75, 4, 4.5, 5, and 5.5 mm
Branemark instrument names are used
Procedure begins with guide drill to half its
diameter at propos implant site
2-mm twist drill to final implant depth
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29. Counterbore to enlarge the coronal portion of
osteotomy in preparation for 3-mm twist drill
3-mm twist drill
Counter-sink drill
Depth gauge
Screw tap
Insert implant attached to fixture mount
Wrench stabilizes fixture mount while fixation
screw is removed
Cover screw inserter
Cover screw placement with small hexagon
screwdriver
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30. Seat Nobel Biocare implant so that
its cover screw is flush with crest of
bone
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31. Sulzer-Calcitek Implant System
Available in 3.25, 4, and 5 mm diameters
Principles applied can be used for other press-
fit endosseous cylindrical implants
Pilot drill for a depth of 8 mm
Rosette bur to half its diameter over the pilot
osteotomy
Intermediate spade drill to enlarge pilot
osteotomy for final depth preparation
Counter bore drill to enlarge coronal portion
Final spade drill
Implant body try-in
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33.
Seat implant with its
plastic cap
Tap implant into
position
Seat calcitek implants
flush with crest of
bone
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34. Innova Endopore Implant
It has a surface macrostructure of sintered
titanium beads
This design greatly increases surface area and
encourages high levels of intraosseous
retention
Technique for seating uses the classic bone
enlargement drill, a steel try-in, and placement
of implant in the press-fit mode
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35. Pilot drill, implant bur, trial fit gauge,
implant placement
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36. Friatec and Frialit 2
These are stepped screw or press-fit TPS-
coated implants designed to increase primary
stability in poor-quality bone
Available in 3.8, 4.5, and 5.5 mm diameter
Primary purchase point with a round drill
Spade drill or twist drill used to full depth
Enlarge receptor site to its final diameter using
stepped drill
Place implant into receptor site, first with finger
pressure and then ratchet them into deeper
threaded environment
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38. Omni-R
Guide drill at potential implant site
Pilot drill to full predetermined depth
Intermediate drill
R2 Hand auger
Seat implant in flush with crest of the bone
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39. Oratronics Spiral
Guide drill used
Pilot drill or spade drill to its final pre-
determined depth
Spiral tap is attached to hand ratchet
Enlarge the osteotomy to chosen length and
width
Implant attached to titanium insert, placed in
the hand wrench and rotated to its final seating
position
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40. SURGICAL PROCEDURES IN
IMPLANTOLOGY
Stage I Surgery
also known as fixture installation stage, is the
procedure for installing Branemark system
implants into bone. This procedure demands
exacting, non-traumatic preparation of the
recipient site and a specific insertion protocol.
Variations in this procedure mainly depends on
the quality and quantity of bone and also on the
load demands on the final prosthesis
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41. High speed hand piece geared up
to run at high torque with a speed
of 1500 to 2000 RPMs, and the
slow speed hand piece at high
torque with speed of approximately
15 to 20 RPMs
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42. Drills used for bone preparation
include: guide drill, 2 mm twist drill,
pilot drill, the 3 mm twist drill, and
countersink
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43. Irrigation unit is used to deliver an
even, steady flow of sterile water to
the surgical site at all times during
high and low speed preparation
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44. Surgical guide stent is placed in the
area to project the future position of
the fixture
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45. Guide drill is the first drill used in
the bone preparation process. It is
designed to penetrate the cortical
layer of the bone
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46. Initial penetration using surgical
guide stent, is initiated using high
speed guide drill at 1500 RPM.
Copious saline irrigation used at all
times
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47. 2 mm twist drill is used second in
the sequence to prepare the site to
2mm in diameter
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48. Site is progressively enlarged to
2mm with a 2mm twist drill at 1500
RPM
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49. Pilot drill is used next. Inferior
portion of the drill is to engage the
2mm prepared site and superior
portion begins the enlargement of
the site
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50. Final orientation and inclination of
the fixture is by using the pilot drill
at high speed, high torque. It has
an 2mm non-cutting edge and a
3mm cutting edge
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51. 3 mm twist drill is fourth drill in bone
preparation. Its used to prepare
bone to its final destination
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52. Implant site is prepared to final
length and width utilizing a 3mm
twist drill operating at high speed
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53. Countersink is the final drill used in
the high speed drilling process. It is
used to create a shelf in the
prepared bony site
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54. Crestal bone carefully prepared
using countersink. Allows superior
aspect of fixture to be placed
crestally or sub-crestally, to avoid
premature loading of the fixture
during stage I healing
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55. Bone tap is the first in the series of
slow speed bone preparation.
Made of titanium and used to
thread the bone prior to implant
placement
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56. Receptor site is tapped utilizing a
titanium tap operating at 15 to 20
RPMs along with copious irrigation
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57. Fixtures are composed of
commercially pure titanium and
range in length from 7 to 20 mm
and width of range 3.75 and 4.0
mm
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