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What Is a
Dental Implant? |
A
dental implant is an
artificial tooth root
replacement and is used in
prosthetic
dentistry to support
restorations that resemble a
tooth or group of teeth. There
are several types of dental
implants. The major
classifications are divided into
osseointegrated implant and the
fibrointegrated implant. Earlier
implants, such as the
subperiosteal implant and the
blade implant were usually
fibrointegrated
[1],
[2].
The most widely accepted and
successful implant today is the
osseointegrated implant,
based on the discovery by
Swedish Professor
Per-Ingvar Brånemark that
titanium can be successfully
fused into
bone when
osteoblasts grow on and into
the rough surface of the
implanted
titanium
[3].
This forms a structural and
functional connection between
the living bone and the implant.
A variation on the implant
procedure is the
implant-supported bridge, or
implant-supported
denture.
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The
Mayan civilization has been
shown to have used the earliest
known examples of endosseous
implants (implants embedded into
bone), dating back over
1,350 years before Per Brånemark
started working with titanium.
While excavating Mayan burial
sites in
Honduras in 1931,
archaeologists found a fragment
of
mandible of Mayan origin,
dating from about 600 AD. This
mandible, which is considered to
be that of a woman in her
twenties, had three tooth-shaped
pieces of shell placed into the
sockets of three missing lower
incisor teeth. For forty
years the archaeological world
considered that these shells
were placed under the nose in a
manner also observed in the
ancient
Egyptians. However, in 1970
a Brazilian dental academic,
Professor
Amadeo Bobbio studied the
mandibular specimen and took a
series of
radiographs. He noted
compact bone formation around
two of the implants which led
him to conclude that the
implants were placed during
life.
In the 1950s research was being
conducted at
Cambridge University in
England to study blood flow in
vivo. These workers devised a
method of constructing a chamber
of titanium which was then
embedded into the
soft tissue of the ears of
rabbits. In 1952 the Swedish
orthopaedic surgeon, P I
Brånemark, was interested in
studying bone healing and
regeneration, and adopted the
Cambridge designed ‘rabbit ear
chamber’ for use in the rabbit
femur. Following several months
of study he attempted to
retrieve these expensive
chambers from the rabbits and
found that he was unable to
remove them. Per Brånemark
observed that bone had grown
into such close proximity with
the titanium that it effectively
adhered to the metal. Brånemark
carried out many further studies
into this phenomenon, using both
animal and human subjects, which
all confirmed this unique
property of titanium.
Although he had originally
considered that the first work
should centre on knee and hip
surgery, Brånemark finally
decided that the mouth was more
accessible for continued
clinical observations and the
high rate of
edentulism in the general
population offered more subjects
for widespread study. He termed
the clinically observed
adherence of bone with titanium
as ‘osseointegration’. In 1965
Brånemark, who was by then the
Professor of
Anatomy at
Gothenburg University in
Sweden, placed the first
titanium dental implant into a
human volunteer, a Swede named
Gösta Larsson.
Over the next fourteen years
Brånemark published many studies
on the use of titanium in dental
implantology until in 1978 he
entered into a commercial
partnership with the Swedish
defense company, Bofors AB for
the development and marketing of
his dental implants. With Bofors
(later to become Nobel
Industries) as the parent
company, Nobelpharma AB (later
to be renamed Nobel Biocare) was
founded in 1981 to focus on
dental implantology. To the
present day over 7 million
Brånemark System implants have
now been placed and hundreds of
other companies produce dental
implants. All dental implants
currently available are axilly
symmetric (cylindrical form) and
do not fit precisely in the
individual tooth socket. For
this reason additional risky and
costly interventions are
regularly required to fill the
gaps between the implant and
bone.
The latest development in
immediate dental implantology
are root analogue
Zirconia implants, which fit
better into the extraction
socket. Long term studies are
lacking
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A
typical implant consists of a
titanium screw (resembling a
tooth root) with a roughened or
smooth surface. The very first
implants were made out of
commercially pure titanium,
however since it was discovered
that the TiAl6V4
alloy offered the same
osseointegration level as
commercially pure titanium, more
and more implants were made out
of TiAl6V4
alloy due to its better tensile
strength and thus fracture
resistance. Today most implants
are made out of the TiAl6V4
alloy and treated either by
plasma spraying, etching or
sandblasting to increase the
surface area and, thus the
integration potential of the
implant. An osteotomy or
precision hole is carefully
drilled into jawbone and the
implant is installed in the
osteotomy.
Implant surgery is typically
performed as an outpatient under
general anesthesia or with
local anesthesia by trained and
certified clinicians including
general dentists, oral surgeons,
and periodontists. An increasing
number of general or cosmetic
dentists as well as
prosthodontists are also placing
implants in relatively simple
cases. The most common treatment
plan calls for several surgeries
over a period of months,
especially if bone augmentation
(bone grafting) is needed to
support implant placements. At
the other end of the surgery
scale, some patients can be
implanted and restored in a
single surgery, in a procedure
labeled "immediate function" and
"teeth in an hour."
A
single implant procedure that
involves an incision and
"flapping" of the gum or gingiva
(to expose the jawbone) takes
about an hour, sometimes longer;
multiple implants can be
installed in a single surgical
session lasting several hours.
At the conclusion, the patient
goes through a period of
recovery, returns to
consciousness and is sent home
with a relative or friend.
Healing and integration of the
implant(s) with jawbone occurs
over several months in a process
called osseointegration. At the
appropriate time, the
restorative or cosmetic dentist
or prosthodontist uses the
implant(s) to anchor crowns or a
prosthetic restoration
containing several "teeth".
Since the implants supporting
the restoration are integrated,
which means they are
biomechanically stable and
strong, the patient is
immediately able to masticate
(chew) normally.
In an immediate function
procedure, the gingiva is not
flapped (Flapless). Instead, the
surgeon removes a small plug of
gingiva directly over the
drilling site. The site is
drilled and the implant is
installed. Then a crown is
immediately added. Patients are
cautioned to give their new
"teeth in an hour" ample
healing/integration time (weeks
or months) before attempting
normal mastication.
There are different approaches
to place dental implants after
tooth extraction. The approaches
are:
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Immediate post-extraction
implant placement.
-
Delayed immediate
post-extraction implant
placement (2 weeks to 3
months after extraction).
-
Late implantation (3 months
after tooth extraction).
According to the timing of
loading of dental implants, the
procedure of loading could be
classified into:
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Immediate loading procedure.
-
Early loading (1 week to 12
weeks).
-
Staged loading (3-6 months).
-
Late loading (more than 6
months).
Most patients need the longer
treatment plan, which has an
excellent history going back
many years.[citation
needed]
Before surgery, with the patient
fully awake or during an earlier
office visit, a prudent
clinician planning mandibular
implants will conduct a
neurosensory examination to rule
out altered sensation, thus
setting a base line on nerve
function. Also prior to surgery,
a panoramic X-ray will be taken
using a metal ball of known
dimension so that calibrated
measurements can be made from
the image (to accurately locate
"vital structures" such as
nerves and the position of
critical anatomical features
such as the mental foramen,
which is the transit point in
the jawbone for the nerve which
innervates the lip and chin).
At edentulous (without teeth)
jaw sites, a pilot hole is
bored into the recipient bone,
taking care to avoid vital
structures (in particular the
inferior alveolar nerve or
IAN within the
mandible). A zone of safety,
usually 2 mm, is the standard of
care for avoiding vital
structures like the IAN. When
computed tomography (3D
X-ray imaging) is used
preoperatively to accurately
pinpoint vital structures, the
zone of safety may be reduced to
1 mm through the use of
computer-aided design of
surgical guides.
Drilling into jawbone usually
occurs in several separate
steps. The pilot hole is
expanded by using progressively
wider drills (typically between
three and seven successive
drilling steps, depending on
implant width and length). Care
is taken not to damage the
osteoblast or bone cells by
overheating. A cooling
saline spray keeps the
temperature of the bone to
below 47 degrees
Celsius (approximately 117
degrees
Fahrenheit). The implant
screw can be
self-tapping, and is screwed
into place at a precise
torque so as not to overload
the surrounding bone (overloaded
bone can die, a condition called
osteonecrosis, which may lead to
failure of the implant to fully
integrate or bond with the
jawbone). Typically in most
implant systems, the osteotomy
or drilled hole is about 1mm
deeper than the implant being
placed, due to the shape of the
drill tip. Surgeons must take
the added length into
consideration when drilling in
the vicinity of vital
structures.
Once properly torqued into the
bone, a cover screw is placed on
the implant, then the gingiva or
gum is sutured over the site and
allowed to heal for several
months for
osseointegration to occur
between the titanium surface of
the implant and jawbone.
After several months the implant
is uncovered in another surgical
procedure, usually under local
anesthetic by the restorative
dentist or prosthodontist, and a
healing abutment and
temporary crown is placed
onto the implant. This
encourages the gum to grow in
the right scalloped shape to
approximate a natural tooth's
gums and allows assessment of
the final
aesthetics of the restored
tooth. Once this has occurred a
permanent
crown will be fabricated and
placed on the implant.
An increasingly common strategy
to preserve bone and reduce
treatment times includes the
placement of a dental implant
into a recent extraction site.
In addition, immediate loading
is becoming more common as
success rates for this procedure
are now acceptable. This can cut
months off the treatment time
and in some cases a prosthetic
tooth can be attached to the
implants at the same time as the
surgery to place the dental
implants.
In all of these approaches,
computer-based guidance has
thrust itself onto the treatment
stage. Not only will 3D digital
imagery yield critical treatment
guidance, the digital data can
be used to manufacture precision
drilling guides, virtually
eliminating surgical errors.
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Complementary procedures
back to top
Sinus lifting is a common
surgical intervention. A dentist
or specialist with proper
training such as an endodontist,
periodontist, prosthodontist, or
oral surgeon thickens the
inadequate part of atrophic
maxilla towards the sinus with
the help of bone transplantation
or bone expletive substance.
This results in more volume for
a better quality bone site for
the implantation.
Bone grafting will be
necessary in cases where there
is a lack of adequate maxillary
or mandibular bone in terms of
front to back (lip to tongue)
depth or thickness; top to
bottom height; and left to right
width. Sufficient bone is needed
in three dimensions to securely
integrate with the root-like
implant. Improved bone height --
which is very difficult to
achieve -- is particularly
important to assure ample
anchorage of the implant's
root-like shape because it has
to support the mechanical stress
of chewing, just like a natural
tooth. If an implant is too
shallow, chewing may cause a
dangerous jawbone crack or full
fracture.
Typically, implantologists try
to place implants at least as
deeply into bone as the crown or
tooth will be above the bone.
This is called a 1:1 crown to
root ratio. This ratio
establishes the target for bone
grafting in most cases. If 1:1
or better cannot be achieved,
the patient is usually advised
that only a short implant can be
placed and to not expect a long
period of usability.
A
wide range of grafting materials
and substances may be used
during the process of bone
grafting / bone replacement.
They include the patient's own
bone (autograft), which may be
harvested from the hip (iliac
crest) or from spare jawbone;
processed bone from cadavers
(allograft); bovine bone or
coral (xenograft); or
artificially produced bonelike
substances (calcium
sulfate with names like
Regeneform; and
hydroxyapatite or HA, which
is the primary form of calcium
found in bone). The HA is
effective as a substrate for
osteoblasts to grow on. Some
implants are coated with HA for
this reason.
Bone graft surgery has its own
standard of care. In a typical
procedure, the clinician creates
a large flap of the gingiva or
gum to fully expose the jawbone
at the graft site, performs one
or several types of block and
onlay grafts in and on existing
bone, then installs a membrane
designed to repel unwanted
infection-causing microbiota
found in the oral cavity. Then
the gingiva is carefully sutured
over the site. Together with a
course of internal antibiotics
and external antibiotic mouth
rinses, the graft site is
allowed to heal (several
months).
The clinician typically takes a
new panoramic x-ray to confirm
graft success in width and
height, and assumes that
positive signs in these two
dimensions safely predicts
success in the third dimension,
depth. Where more precision is
needed, usually when mandibular
implants are being planned, a 3D
or cone beam X-ray may be called
for at this point to enable
accurate measurement of bone and
location of nerves and vital
structures for proper treatment
planning. The same X-ray data
set can be employed for the
preparation of computer-designed
placement guides.
Correctly performed, a bone
graft produces live vascular
bone which is very much like
natural jawbone and is therefore
suitable as a foundation for
implants.
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For dental implant procedure to
work, there must be enough bone
in the jaw, and the bone has to
be strong enough to hold and
support the implant. If there is
not enough bone, more may need
to be added with a bone graft
procedure discussed earlier.
Sometimes, this procedure is
called bone augmentation. In
addition, natural teeth and
supporting
tissues near where the
implant will be placed must be
in good health.
In all cases, what must be
addressed is the functional
aspect of the final implant
restoration, the final
occlusion. How much force per
area is being placed on the bone
implant interface? Implant loads
from chewing and parafunction
can exceed the physio
biomechanic tolerance of the
implant bone interface and/or
the titanium material itself,
causing failure. This can be
failure of the implant itself
(fracture) or bone loss, a
"melting" or resorption of the
surrounding bone.
The dentist must first determine
what type of prosthesis will be
fabricated. Only then can the
specific implant requirements
including number, length,
diameter, and thread pattern be
determined. In other words, the
case must be reverse engineered
by the restoring dentist prior
to the surgery. If bone volume
or density is inadequate, a bone
graft procedure must be
considered first. The restoring
dentist may consult with the
periodontist, endodontist, oral
surgeon, or another trained
general dentist to co-treat the
patient. Usually, physical
models or impressions of the
patient's jawbones and teeth are
made by the restorative dentist
at the implant surgeons request,
and are used as physical aids to
treatment planning. If not
supplied, the implant surgeon
makes his own or relies upon
advanced computer-assisted
tomography or a cone beam CAT
scan to achieve the proper
treatment plan.
Computer simulation software
based on CAT scan data allows
virtual implant surgical
placement based on a barium
impregnated prototype of the
final prosthesis. This predicts
vital anatomy, bone quality,
implant characteristics, the
need for bone grafting, and
maximizing the implant bone
surface area for the treatment
case creating a high level of
predictability. Computer
CAD/CAM milled or stereo
lithography based drill guides
can be developed for the implant
surgeon to facilitate proper
implant placement based on the
final prosthesis occlusion and
aesthetics.
Treatment planning software can
also be used to demonstrate
"try-ins" to the patient on a
computer screen. Software
products like
Materialise'
SimPlant (simulated implant)
use the digital data from a CAT
scan (such as an iCAT or a
NewTom) to provide extremely
accurate simulations that are
easily understood by patients.
When options have been fully
discussed between patient and
surgeon, the same software can
be used to produce precision
drill guides.
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Dental implant success is
related to operator skill,
quality and quantity of the bone
available at the site, and also
to the patient's oral hygiene.
Various studies have found the
10 year success rate of implants
to be between 90 and 95%.
Patients who smoke experience
significantly poorer success
rates.
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Failure of a dental implant is
often related to failure to
osseointegrate correctly. A
dental implant is considered to
be a failure if it is lost,
mobile or shows peri-implant
(after implant) bone loss of
greater than 1.0 mm in the first
year and greater than 0.2mm a
year thereafter.
Dental implants are not
susceptible to
dental caries but they can
develop a
periodontal condition called
peri-implantitis. The cause may
be infection that was introduced
during surgery; or failure by
the patient to follow correct
oral hygiene routines. In
either case, inflammation in the
bone surrounding the implant
causes bone loss (recession)
which ultimately may lead to
failure, often evidenced by the
ability to "spin" an implant.
Peri-implantitis is often dealt
with pre-emptively by clinicians
who prescribe a course of
antibiotics in the days prior to
surgery; and post-surgically
with another course of
antibiotics and special oral
rinses. Since peri-implantitis
is generally easy to see on
standard panoramic and
periapical X-rays, prudent
clinicians who suspect the
problem will take an X-ray soon
after surgery, and again at
staged intervals
post-operatively.
Risk of failure is increased in
smokers. For this reason
implants are frequently placed
only after a patient has stopped
smoking as the treatment is very
expensive. More rarely, an
implant may fail because of poor
positioning at the time of
surgery, or may be overloaded
initially causing failure to
integrate. If smoking and
positioning problems exist prior
to implant surgery, clinicians
often advise patients that a
bridge or partial denture rather
than an implant may be a better
solution.
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There are no absolute
contraindications to implant
dentistry, however there are
some systemic, behavioral and
anatomic considerations that
should be considered.
Particularly for mandibular
(lower jaw) implants, especially
in the vicinity of the
mental foramen (MF), there
must be sufficient alveolar bone
above the
mandibular canal also called
the inferior alveolar canal or
IAC (which acts as the conduit
for the
neurovascular bundle
carrying the inferior alveolar
nerve or IAN).
Failure to precisely locate the
IAN and MF invites surgical
insult by the drills and the
implant itself. Such insult may
cause irreparable damage to the
nerve, often felt as a
paresthesia (numbness) or
dysesthesia (painful numbness)
of the gum, lip and chin. This
condition may persist for life
and may be accompanied by
unconscious drooling.
Lack of sufficient alveolar bone
is another contraindication to
the procedure. Typically, a
preoperative in-office panoramic
X-ray is taken to establish
(with allowances for image
distortion, a known problem with
panoramic X-rays) in two
dimensions (height and width)
the amount of available bone. A
bone graft or augmentation
procedure may be performed and
allowed to heal several months
before implantation surgery. A
new panoramic X-ray will help
determine if the graft was
successful.
This is an important step
inasmuch as improved bone height
is much more difficult to
achieve than more increased bone
depth. For mandibular grafts, a
3D or cone beam X-ray enables
measurement of bone height (top
to bottom), width (left and
right) and depth (front to back)
to an accuracy of 0.1mm. The
precision of cone beam has
stimulated a new industry that
produces computer-designed
surgical guides based on the
cone beam X-ray's digital data.
These surgery aids are employed
by implantologists to precisely
locate and drill into the
mandible and maxilla, and to
avoid vital structures.
Uncontrolled type II diabetes is
a significant relative
contraindication as healing
following any type of surgical
procedure is delayed due to poor
peripheral blood circulation.
Anatomic considerations include
the volume and height of bone
available. Often an ancillary
procedure known as a block graft
or sinus augmentation are needed
to provide enough bone for
successful implant placement.
There is new information about
intravenous and oral
bisphosphonates (taken for
certain forms of breast cancer
and osteoporosis, respectively)
which may put patients at a
higher risk of developing a
delayed healing syndrome called
osteonecrosis. Implants are
contraindicated for some
patients who take intravenous
bisphosphonates.
The many millions of patients
who take an oral bisphosphonate
(such as Actonel, Fosamax and
Boniva) may be advised to stop
the administration prior to
implant surgery, then resume
several months later. But this
protocol may not be necessary.
As of January, 2008, an oral
bisphosphonate study reported in
the February 2008 Journal of
Oral and Maxillofacial Surgery,
reviewing 115 cases that
included 468 implants, concluded
"There is no evidence of
bisphosphonate-associated
osteonecrosis of the jaw in any
of the patients evaluated in the
clinic and those contacted by
phone or e-mail reported no
symptoms." (JOMS, Volume 66,
Issue 2, Ppgs 223-230).
The American Dental Association
had addressed bisphosphonates in
an article entitled "Bisphosphonate
medications and your oral
health," (JADA, Vol. 137, page
1048, July 2006.) In an
Overview, the ADA stated "The
risk of developing BON [bisphosphonate-associated
osteonecrosis of the jaw] in
patients on oral bisphosphonate
therapy appears to be very
low...". The ADA Council on
Scientific Affairs also employed
a panel of experts who issued
recommendations [for clinicians]
for treatment of patients on
oral bisphosphonates, published
in June, 2006. The overview may
be read online at ada.org but it
has now been superseded by a
huge study -- encompassing over
700,000 cases -- entitled "Bisphosphonate
Use and the Risk of Adverse Jaw
Outcomes." Like the 2008 JOMS
study, the ADA study exonerates
oral bisphosphonates as a
contraindication to dental
implants. (JADA, January 2008,
139:23-30).
Bruxism (tooth clenching or
grinding) is another
contraindication. The forces
generated during bruxism are
particularly detrimental to
implants while bone is healing;
micromovements in the implant
positioning are associated with
increased rates of implant
failure. Bruxism continues to
pose a threat to implants
throughout the life of the
recipient. Natural teeth contain
a periodontal ligament allowing
each tooth to move and absorb
shock in response to vertical
and horizontal forces. Once
replaced by dental implants,
this ligament is lost and teeth
are immovably anchored directly
into the jaw bone. This problem
can be minimized by wearing a
custom made mouthguard (such an
NTI appliance) at night.
Postoperatively, after implants
have been placed, there are
physical contraindications that
prompt rapid action by the
implantology team. Excessive or
severe pain lasting more than
three days is a warning sign, as
is excessive bleeding. Constant
numbness of the gingiva (gum),
lip and chin -- usually noticed
after surgical anesthesia wears
off -- is another warning sign.
In the latter case, which may be
accompanied by severe constant
pain, the standard of care calls
for diagnosis to determine if
the surgical procedure insulted
the IAN. A 3D cone beam X-ray
provides the necessary data, but
even before this step a prudent
implantologist may back out or
completely remove an implant in
an effort to restore nerve
function because delay is
usually ineffective. Depending
upon the evidence visible with a
3D X-ray, patients may be
referred to a specialist in
nerve repair. In all cases,
speed in diagnosis and treatment
are necessary.
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In the United States,
implantology is not a recognized
specialty. Various ‘implant
surgeons’ play a role in the
placement of dental implants.
Specialists with adequate
comprehensive training such as
Prosthodontists are ideally
preferred. Other specialists
such as periodontists, oral
surgeons, and endodontists
participate in the placement of
implants. Also, some general
dentists trained and skilled in
implant surgery may place dental
implants. However caution is
warranted as a rigorous training
cannot be substituted with a
weekend course. It is almost
always necessary for advanced
bone surgical skills (such as
grafting) to be employed during
implant treatment. Therefore, it
is important for the ‘implant
surgeon’ to be able to have
surgical options available,
through adequate training, to
serve the needs of patients. It
is common for implant care to be
coordinated amongst the
designated ‘implant surgeon’ and
the dentist for the placement of
the implant and restoration of
the implant with a tooth, teeth,
or some other form of a
prosthesis such as an implant
supported over-denture or
perhaps a hybrid prosthesis.
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^ James RA.
Subperiosteal implant design
based on peri-implant tissue
behavior. N Y J Dent
1983;53:407-414
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^ Linkow LI, Kohen
PA. Benefits and risks of
the endosteal blade implant
(Harvard Conference, June
1978). J Oral Implantol
1980;9:9-44
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^ Branemark PI,
Hansson BO, Adell R, Breine
U, Lindstrom J, Hallen O, et
al. Osseointegrated implants
in the treatment of the
edentulous jaw. Experience
from a 10-year period. Scand
J Plast Reconstr Surg Suppl
1977;16:1-132
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