Mechanical Principles Involved in Tooth Extraction 1

EXODONTIA
Mechanical Principles Involved in
Tooth Extraction 1
Senior Lecturer Dr. Haydar Munir Salih Alnamir
BDS, PhD (Board Certified)

Mechanical Principles Involved in Tooth
Extraction
•The removal of teeth from the alveolar
process requires the use of the following
mechanical principles and simple machines:
1. the lever,
2. the wedge, and
3. the wheel and axle.

1. The lever action
• Elevators are used primarily as levers. A lever is a
mechanism for transmitting a modest force—with
the mechanical advantages of a long lever arm and
a short effector arm—into a small movement against
great resistance
• An example of the use of a lever is when a Crane
pick is inserted into a purchase point placed in a
tooth and then is used to elevate the tooth

2. The wedge action
• The wedge is useful in several different ways for the
extraction of teeth.
• First, the beaks of extraction forceps are usually narrow at
their tips; they broaden as they go superiorly. When forceps
are used, there should be a conscious effort made to force the
tips of the forceps into the periodontal ligament space at the
bony crest.
• This uses the tooth root as a wedge to expand the bone; as the
beaks of the forceps are pressed apically on the root, they will
help force the tooth out of the socket

2. The wedge action
• The wedge principle is
also useful when a straight
elevator is used to luxate
a tooth from its socket. A
small elevator is wedged
into the periodontal
ligament space, which
displaces the root toward
the occlusion and thus out
of the socket

3. The wheel and axle action
• the wheel and axle, which is most closely identified
with the triangular, or pennant- shaped, elevator.
When one root of a multiple-rooted tooth is left in
the alveolar process, the pennant-shaped elevator,
such as a Cryer, is positioned into the socket and
turned.
• The handle then serves as the axle, and the tip of
the triangular elevator acts as a wheel and engages
and elevates the tooth root from the socket

The goal of forceps use is threefold:
(1) expansion of the bony socket by use of the wedge-
shaped beaks of the forceps and the movements of the
tooth itself with the forceps,
(2) twisting of conical roots to disrupt periodontal
ligaments, and
(3) removal of the tooth from the socket.

Forceps can apply five major motions to
luxate teeth.
The first is apical pressure,
which accomplishes two
goals. (1) Although the
tooth moves in an apical
direction minimally, the
tooth socket is expanded
by the insertion of the
beaks down into the
periodontal ligament space

1. Apical pressure
(2) A second accomplishment of apical
pressure is that the center of rotation
of the tooth is displaced apically which
results in greater movement of the
expansion forces at the crest of the
ridge and less force moving the apex of
the tooth lingually .This process
decreases the chance for apical root
fracture.

luxate teeth.
• The second major pressure or movement applied
by forceps is the buccal force. Buccal pressures
result in expansion of the buccal plate,
particularly at the crest of the ridge .
• Although buccal pressure causes expansion forces
at the crest of the ridge, it is important to
remember that it also causes lingual apical
pressure. Thus excessive force can fracture buccal
bone or cause fracturing of the apical portion of
the root.

luxate teeth.
• Third, lingual or palatal pressure is similar to the
concept of buccal pressure but is aimed at
expanding the linguo-crestal bone and, at the
same time, avoiding excessive pressures on the
buccal apical bone. Because lingual bone tends to
be thicker than buccal bone in posterior areas of
the mouth, limited bone expansion occurs.

3. Lingual or palatal pressure

luxate teeth.
• Because maxillary buccal bone is usually thinner and palatal
bone is a thicker cortical bone, maxillary teeth are usually
removed by stronger buccal forces and less vigorous palatal
forces.
• In the mandible, buccal bone is thinner from the midline
posteriorly to the area of molars. Therefore incisors,
canines, and premolars are removed primarily as a result of
strong sustained buccal force and less vigorous lingual
pressures.

luxate teeth.
• Fourth, rotational pressure, as the name implies,
rotates the tooth, which causes some internal
expansion of the tooth socket and tearing of
periodontal ligaments.
• Teeth with single, conical roots (such as incisors,
canines, and mandibular premolars) and those with
roots that are not curved are most amenable to
luxation by this technique .Teeth that have other
than conical roots or that have multiple roots—
especially if those roots are curved—are more likely
to fracture under this type of pressure.

luxate teeth.
• Finally, tractional forces are useful for delivering
the tooth from the socket once adequate bony
expansion is achieved. As mentioned previously,
teeth should not be pulled from their sockets.
Tractional forces should be limited to the final
portion of the extraction process and should be
gentle . If excessive force is needed, other
maneuvers should be performed to improve root
luxation

Procedure for Closed Extraction
The correct technique for any situation should lead to an
atraumatic extraction; the wrong technique commonly results
in an excessively traumatic and lengthy extraction.
Whatever technique is chosen, the three fundamental
requirements for a good extraction remain the same:
(1) adequate access and visualization of the field of surgery,
(2) an unimpeded pathway for the removal of the tooth, and
(3) the use of controlled force to luxate and remove the tooth.

General steps make up the closed extraction
procedure.
Step 1 involves loosening of the soft tissue attachment from
the cervical portion of the tooth.
The purpose of loosening the soft tissue from the tooth is
twofold:
(1) First, it allows the surgeon to ensure that profound
anesthesia has been achieved
(2) The second reason that soft tissue is loosened is to allow the
elevator and tooth extraction forceps to be positioned more
apically, without interference from or impingement on the
gingiva

Step 1 involves loosening of the soft tissue
attachment from the cervical portion of the tooth.

General steps make up the closed
extraction procedure.
• Step 2 involves luxation of the tooth with a dental
elevator. The luxation of the tooth begins with a dental
elevator, usually the straight elevator
• Elevation should occur at the mesial and distal buccal
aspects of the root. No elevation should be attempted along
buccal bone because it can be easily fractured or the
surgeon can lose control and cause soft tissue injury.

Step 2 involves luxation of the tooth with a
dental elevator
• The straight elevator is inserted perpendicular to
the tooth into the interdental space, after
reflection of the interdental papilla
• Luxation of teeth with a straight elevator should
be performed with caution. Excessive forces can
damage and even displace the teeth adjacent to
those being extracted.

Step 2 involves luxation of the tooth with a
dental elevator

• Step 3 involves adaptation of the forceps to the
tooth. The proper forceps are now chosen for the
tooth to be extracted. The beaks of the forceps
should be shaped to adapt anatomically to the
tooth, apical to the cervical line, that is, to the
root surface. (A few exceptions to this include
the cowhorn forceps.)

Step 3 involves adaptation of the forceps to
the tooth.
• Care must be taken to confirm that the tips of the forceps
beaks are beneath the soft tissue and not engaging an
adjacent tooth.
• The beaks of the forceps must be held parallel to the long
axis of the tooth so that the forces generated by the
application of pressure to the forceps handle can be
delivered along the long axis of the tooth for maximal
effectiveness in dilating and expanding alveolar bone
• The forceps are then forced apically as far as possible to
grasp the root of the tooth as apically as possible

Step 3 involves adaptation of the forceps to
the tooth.

• Step 4 involves luxation of the tooth with forceps.
• The major portion of the force is directed toward the thinnest
and therefore weakest bone. Thus, with all teeth in the maxilla
and all but molar teeth in the mandible, the major movement is
labial and buccal (i.e., toward the thinner layer of bone).
• The surgeon uses slow, sustained, steady force to displace
the tooth buccally, rather than a series of rapid, small
movements that do little to expand bone. The motion is
deliberate and slow, and it gradually increases in force. The
tooth is then moved again toward the opposite direction with
slow, deliberate, strong pressure

The following three factors must be
reemphasized
(1) The forceps must be apically seated as far as
possible and reseated periodically during the
extraction;
(2) the forces applied in the buccal and lingual
directions should be slow, deliberate pressures and
not jerky wiggles; and
(3) the force should be held for several seconds to
allow the bone time to expand.

Step 4 involves luxation of the tooth with
forceps.

• Step 5 involves removal of the tooth from the
socket. Once alveolar bone has expanded
sufficiently and the tooth has been luxated, a
slight tractional force, usually directed buccally,
can be used. Tractional forces should be
minimized because this is the last motion that is
used once the alveolar process is sufficiently
expanded and the periodontal ligament is
completely severed

Role of the Opposite Hand
• (1) The left hand is responsible for reflecting the soft
tissues of the cheeks, lips, and tongue to provide
adequate visualization of the area of surgery. The left
hand helps protect other teeth from the forceps, should
it release suddenly from the tooth socket.
• (2) The left hand, and sometimes arm, helps stabilize the
patient’s head during the extraction process. In some
situations, greater amounts of force are required to
expand heavy alveolar bone; therefore the patient’s
head requires active assistance to be held steady.

Role of the Opposite Hand
3) The opposite hand plays an important role in supporting
and stabilizing the jaw when mandibular teeth are being
extracted. The opposite hand is often necessary to apply
considerable pressure to expand heavy mandibular bone, and
such forces can cause discomfort and even injury to the TMJ
unless a steady hand counteracts them.
(4) Finally, the opposite hand supports the alveolar process
and provides tactile information to the operator concerning
the expansion of the alveolar process during the luxation
period.

Mechanical Principles Involved in Tooth Extraction 1

Mechanical Principles Involved in Tooth Extraction 1

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Mechanical Principles Involved in Tooth Extraction 1