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Description  |
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TECHNICAL FIELD
This invention relates to dental implants and, more particularly, to
submergible screw-type implants.
BACKGROUND ART
Screw-type implants are well known in the art. U.S. Pat. No. 3,499,222 of
L. I. Linkow et al. discloses screw-type implants which may be buried in
the alveolar ridge crest bone of a patient in an edentulous region. The
implant has a threaded lower portion which may be screwed into an opening
created in the bone after the tissue has been displaced. A coronal portion
protrudes above the bone and is used to support an artificial dental
appliance, e.g. an artificial tooth or bridge.
In more recent years submergible implants have been created in which the
threaded portions of the implants can be completely embedded in the bone.
They may then be covered with tissue and allowed to remain in place while
new bone grows around the implant and through vent holes in it. Once it is
firmly anchored in new bone (3 to 6 months), the tissue is reopened and an
upper post portion is screwed into the implant portion and is used to
mount the artificial dental device.
It is advantageous when installing an implant portion in the patent's bone,
if the implant is self-tapping in a bore created in the bone. This causes
it to be anchored better. Also, it would be advantageous if the bone chips
created during a self-tapping operation were deposited into the bore or
opening because these chips promote faster bone growth because of their
autogenous nature.
In order to align the artificial tooth or other dental devices with the
other teeth of the patient, it may be necessary to have the post portion
at an angle to the implant portion. This may be accomplished by bending
the post portion so that its head is at an angle to the threaded shaft.
This bending may be accomplished before the post is threaded into the
implant portion or afterward. If the post is bent before attachment to the
implant, the proper alignment is difficult to achieve. If bent after
attachment, there is a danger that too much stress will be put on the
implant portion and it will loosen in the bone and fail. Also bending the
post may fatigue the metal of the post and cause breakage.
DISCLOSURE OF THE INVENTION
The present invention is directed to a dental implant which, in its
preferred form, is of the submergible screw type with a longitudinal
channel or slot through the threads so as to improve their self-tapping
ability. The implant also has an angled swivelable connector to allow a
support post for an artificial dental appliance to be positioned in proper
alignment with other teeth in the patient's mouth without applying stress
to the implant.
In an illustrative embodiment of the invention, the implant portion of the
device includes a threaded region that contains a longitudinal channel
through a portion of the outer parts of the threads. The channel is wider
toward its bottom. One side of the channel is at a right angle to the
implant circumference so as to create a cutting edge that assists in the
formation of a self-tapping capability for the implant when it is
installed in a bore or opening in the patient's bone. The other side of
the channel is at an oblique angle to the circumference.
The channel guides bone chips created during the threading of the implant
toward the base of the bore in the bone. By terminating the channel below
the uppermost threads, epithelial tissue is prevented from growing down
into the bone along the channel.
The post or abutment portion of the implant which supports an artificial
dental appliance may be a straight portion on to which the appliance is
threaded. However, in situations where it must be at an angle to the
implant portion, the abutment may be a separate piece from the implant
portion and may be attached thereto at an angle by means of a connection
portion of the abutment. The connection portion may be in the form of a
rotatable beveled collar, a ball and socket joint, or other suitable means
that allow the post to swivel about the axis of the implant portion and/or
to assume various angles with respect to that axis. Once in place, means
are provided for securing the abutment against further movement with
respect to the implant portion. As a result the implant can assume a
desired angle to assure proper alignment of the artificial dental
structure with the other teeth of the patient along the occlusal plane.
In one version the abutment may include an elastic ring. This ring flexibly
separates an upper portion and lower portion of the abutment, much in the
manner of a shock absorber. With this arrangement some of the shock of
mastication is buffered so that it is not applied directly to the screw
implant.
The present invention also contemplates a unique surgical method. With this
method an incision is made in the tissue covering the alveolar ridge crest
bone. This underlying bone is then exposed and a bore is drilled into the
bone at a depth sufficient to hold the implant portion of the device. The
bore is made slightly smaller in diameter than the implant device and is,
at an angle which will allow it to engage the major portion of the
available bone. Then the implant device is threaded into the remaining
bone about the bore utilizing its self-tapping threads and the
self-tapping feature of the channel along its length. It is typically
buried at a depth such that it is submerged below the upper surface in the
bone and is completely buried in the bone.
During the insertion procedure bone chips are removed from walls of the
bore while forming the grooves in the bone which match the threads in the
implant. These bone chips drop along the channel to the base of the bore
and help to promote growth of new bone which firmly anchors the implant in
place.
Threading of the implant portion into place may be accomplished with a
hexagonal projection or recess located at the free end of the implant
portion. This hexagonal section is connected to a wrench-type device to
screw the implant into the bone.
Once secured in place a cover of minimal height may be attached to the
exposed surface of the implant portion by a screw passing through the
cover and threaded into an aperture in that surface. The tissue may then
be sutured over the implant cover. New bone is allowed to grow and to
anchor the cover and implant firmly in place. Several weeks or months
later, the tissue is opened again and the cover is removed. A threaded
abutment or post is then attached to the threaded aperture in the end of
the implant portion. This abutment is used for supporting the artificial
dental appliance.
The angle at which the implant portion is located in the bone may not be
the most conducive to the proper alignment of the artificial tooth or
other dental devices with the remaining teeth of the patient. As a result,
the abutment includes an angled, swivelable connection portion for
attaching the abutment to the implant portion. In one embodiment fixed
angular devices which are rotatable about the longitudinal axis of the
implant are utilized, and in another embodiment the part is continuously
swivelable to any desired angle. In either case, after the abutment or
support for the artificial tooth is at the proper angle, it is locked such
that it remains in that position. Finally, the tissue is closed about the
abutment and the artificial tooth or bridge support is cemented or screwed
to the abutment.
BRIEF DESCRIPTION OF THE DRAWINGS
The foregoing and other features of the present invention will be more
readily apparent from the following detailed description and drawings of
illustrative embodiments of the invention, in which:
FIG. 1 is a schematic cross section of the side of a patient's face showing
the alveolar ridge crest with a screw type implant according to the
present invention installed therein;
FIG. 2 is an enlarged view of an illustrative embodiment of the implant
portion of the device of FIG. 1 with an external hex projection;
FIG. 3 is a top view of the implant portion of FIG. 2 showing the external
hex portion;
FIG. 4 is a cross-sectional view through the implant portion of FIG. 2
along line 4--4 showing the cross-sectional shape of the channel according
to the present invention;
FIG. 5 is an implant portion of a screw-type implant according to the
present invention with an internal hex recess;
FIG. 6 is an illustrative embodiment of a completed screw-type implant with
an angularly positioned threaded shaft attached thereto;
FIG. 7 is a cross-sectional view of a ball and socket connection portion of
an abutment according to the present invention;
FIG. 8 illustrates a modification of the ball and socket joint of FIG. 7;
FIG. 9 illustrates a further modification of the ball and socket joint of
FIG. 7;
FIG. 10 is a ball and socket joint connection portion with a stationary
ball;
FIGS. 11A and 11B are cross-sectional views of a unitary inner casing and a
two-part inner casing, respectively;
FIG. 12 is a side view of a healing collar according to the present
invention;
FIGS. 13 and 14 are front and side sectional views of an artificial tooth
with an abutment according to FIG. 7;
FIG. 15 is a cross-sectional view of an embodiment of an abutment with a
shock-absorbing cushion; and
FIG. 16 is an alternative embodiment of the screw of the shock-absorbing
abutment of FIG. 15.
DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS
The present invention contemplates at least a two part screw-type dental
implant, i.e, an implant portion 10 which is buried in the bone of the
patient and a post or abutment portion 20 which is attached thereto and
which supports an artificial tooth structure 30. As shown in FIG. 1, an
implant screw portion 10 is located in a bore in the aveolar crest 11 at
an angle that causes it to be in the center of the thickest portion of
good available bone. The abutment 20 is attached both to the implant
portion 10 and the artificial tooth 30, and is set so that the tooth is at
an angle to the implant which causes the tooth to be in proper alignment.
In FIGS. 2 and 3 the screw implant portion 10 of FIG. 2 is illustrated in
more detail. This implant portion 10 contains threads 13 which extend over
the middle region of the implant portion. These threads may have a flat
bottom and be angled up to form a Christmas tree shape in cross section.
The lower half of the implant portion 10 contains a cavity 14 (shown in
dotted line). Also, spaced about the lower end of the implant are holes or
vents 16, 16a and 16b, which penetrate from its exterior to the interior
cavity 14. The purpose of these vents is to allow new bone to grow through
and into the center cavity in order to firmly anchor the implant in the
patient's bone. The upper surface 17 of the implant portion defines a
threaded aperture 19 which is used to connect the abutment 20 to the
implant portion 10. The projecting structure 12 which forms surface 17 has
a hexagonal shape as shown more clearly in FIG. 3. This hexagonal shape
allows a tool, e.g. a wrench, to be used to rotate the implant portion so
as to thread it into the patient's bone.
According to the present invention a channel 18 is cut through the threads
13 and possibly into the outer casing of the implant portion 10. As
depicted in dotted line in FIG. 3 and in cross-section in FIG. 4, the
channel 18 is one of three channels 18, 18a, 18b in a typical implant
portion. These channels are made to intersect the respective vents 16, 16a
and 16b which are spaced at angles of 120.degree. about the circumference
of the implant portion 10. The channels do not extend completely toward
the upper surface 12 in order to prevent tissue from growing down along
the channel, and to prevent the incursion of food and bacteria. It should
be particularly noted in FIG. 4 that the channels 18 have one edge which
is at about 90.degree. to the circumference of the implant, i.e., surface
18', and another more obliquely shaped edge, i.e. surface 18".
During installation of the implant, an incision is made in the gum tissue
of the patient and the underlying bone is exposed. Then a drill or burr is
used to make an opening or bore hole in the bone which is slightly larger
in diameter than the implant portion body 10, but which is not as wide as
the threads 13. A wider counterbore may be provided to accommodate a
protection collar as explained subsequent)y. Next the implant is inserted
up to the first thread in the opening in the bone. A tool, such as a
wrench, is used to engage the hex portion 12 and to rotate the implant.
The threads 13 are made to be self-tapping so that the implant portion
will begin to screw down into the patient's bone. If necessary, a bone tap
can be used to create grooves in the hard upper cortical bone prior to
insertion of the implant portion. The right angle surface 18' of the
channel also has self-tapping properties so as to ease the insertion of
the implant, once it has reached the depth of the channels 18. Further
turning of the implant causes the right angle surface 18' to scrape off
bone as the implant is being threaded and to push the resulting bone chips
forward. This causes the bone chips to fall through the channels 18 and
into the area of the vents 16 where they may penetrate into the interior
cavity 14. To facilitate this, the channels 18 are made wider towards the
vents 16.
As a result of this structure, bone chips created during the implant
procedure tend to accumulate at the base of the implant in the patient's
bone. Because of the autogenous nature of these bone chips they promote
the growth of new bone in the area and speed the formation of new bone
around and through the implant such that it is anchored in place more
rapidly.
In FIG. 5 there is shown an implant portion 10 which is nearly identical to
that shown in FIG. 1. The principal difference is that, rather than having
a hexagonal projection useful for applying torque to the implant, a
hexagonal recess 12' is provided. In addition, the threaded aperture 19'
is made somewhat smaller and is located at the base of hexagonal recess
12'. As explained previously, the threaded aperture 19, is used for
attaching the implant portion of the device to the abutment portion. One
embodiment of such an attachment is shown in FIG. 6.
In FIG. 6 the upper part of the implant portion 10 is shown partly broken
away and partly in section. It is shown partly broken away to exhibit the
interior cavity 14 and the threads 13. Towards the upper part of the
implant portion it is shown in cross section. This implant portion is like
that shown in FIG. 5 with a hexagonal recess 12' for rotating it into
position in the bone. As shown in FIG. 6 the screw type implant portion 10
is connected to an abutment portion 20 that includes a transitional collar
21, an angled threaded shaft 24, and a tooth support cylinder 31. The
threaded shaft 24 has its lower end screwed into threaded aperture 19' in
the implant portion 10. The upper end of the threaded shaft, which is set
at an angle to the lower end, is received within a threaded aperture 35 in
tooth support cylinder 31. This cylinder 31 contains a recessed portion 32
which may be utilized in fixing on to the cylinder via cement or some
other convenient and well known method, a porcelain, plastic, or other
dental tooth-colored veneering material in the form of an artificial
tooth.
The transitional collar 21 is located between the upper end of the implant
portion 10 and the cylinder 31. This collar has an angled upper surface 25
and a perpendicular lower surface 23. The angle of the upper surface is
made to equal the angle of the upper part of the angled shaft 24. While
collar 21 surrounds threaded shaft 24, it does not engage its threads.
During an installation procedure the implant portion 10 is located in the
patient's bone as previously described. The gingival tissues can then be
replaced over the implant portion and several weeks or months allowed to
pass while new bone grows around and through the implant portion. However,
alternatively the artificial tooth can be connected to the implant
immediately. Whichever manner is chosen, the attachment is accomplished by
selecting an angled shaft and transition collar which have an angle which
will cause the artificial tooth to be correctly aligned with the other
teeth of the patient. Therefore the dentist or oral surgeon must be
provided with a variety of such shafts and collars which are at standard
angles. Also during the insertion procedure the surgeon must appropriately
angle the opening in the bone so it penetrates a reasonably thick area of
good bone. This may require that the opening in the bone be drilled at an
angle in order to avoid penetrating a nearby sinus cavity, passing
completely through the bone, or contacting a nerve bundle. However, in
selecting the angle at which the implant is buried, care must be taken to
make sure that this angle will accommodate one of the standard angles
available with the threaded shafts and collars, e.g. 10, 20 or 30 degrees,
so as to result in alignment between the new artificial tooth and the
remaining teeth of the patient.
Once the threaded shaft 24 is engaged with the implant portion 10, the
collar 21 is slipped over the free end of the shaft. Then the shaft is
rotated so that it is firmly secured in the implant portion and is
extending in the proper direction. With the collar in place over this
shaft, the cylinder portion 31 is threaded over the open or free end of
the shaft until it makes tight contact with the upper surface of the
collar and begins to squeeze the collar between the cylinder and implant
portions. Notches and recesses 22 and 27 are provided in the mating
surfaces such that, once the parts are screwed together, these notches and
recesses engage each other and prevent unintentional unscrewing of the
portions of the implant. With this firm attachment completed, the
artificial tooth can then be attached over the abutment cylinder 31.
In FIG. 6 the level of the patient's bone is shown as dotted line 70. Since
the implant portion is submerged in the bone, the line 70 intersects the
lower portion of the transitional collar 21. The gum tissue line 72 is
towards the upper portion of the transitional collar. As a result the
collar acts a barrier to prevent the encroachment of bacteria and food
into the interior portion of the collar and the hex recess of the implant
portion.
With the embodiment of FIG. 6 fixed angles are provided to the dentist and
he must work with the standard angles and the angle which he creates for
the bore in the patient's bone, in order to assure proper alignment of the
teeth. In some patients who have had serious bone disease, the amount of
available good bone is limited and the dentist has only a limited amount
of freedom in selecting the angle at which the bore for the implant is
made. Also with the embodiment of FIG. 6 it is necessary for a dentist to
keep a stock of various angled shafts and collars. The difficultly
presented by the type of implant in FIG. 6 is overcome by the implant
shown in FIG. 7.
In FIG. 7 the angled shaft and transition collar are replaced with a ball
and socket joint which allows for the setting of the angled relationship
between the implant portion and the abutment portion at any selected angle
within the range of motion of the ball and socket joint, e.g. up to 30-40
degrees. In FIG. 7 the threaded cavity 19 receives the threaded shaft of a
lower or inner abutment casing 42. This casing has a generally Y-shape
with the lower portion being the shaft that extends into and engage the
threads of cavity 19. The upper portion of casing 42 has a hemispherical
surface 45 such that it can receive a ball 46. An upper or outer casing 44
screws onto outer threads of the inner casing 42 such that ball 46 is
trapped within the abutment casing, but is free to rotate therein so as to
create a ball and socket joint.
A relatively large set screw 48 penetrates the ball completely. This set
screw 48 has an internal threaded cavity 55 which passes through an upper
hexagonal projection 56. Once the implant portion 10 has been located in
the bone at the optimal angle, the ball 46 is rotated such that the center
axis of the set screw is at the proper angle for mounting of an artificial
tooth in line with other teeth in the patient's mouth. Then the hexagonal
portion 56 is rotated with a wrench or other tool so the set screw comes
into extreme frictional contact with the hemispherical surface 45 of inner
casing 42. This prevents further rotation of the ball and the set screw.
The artificial tooth structure in the embodiment of FIG. 7 has an interior
cylinder 50, about which the porcelain, plastic or other dental material
is formed to create the artificial tooth structure. This cylinder 50 with
the artificial tooth structure mounted thereon, is placed on top of the
hexagonal projection 56 and is then attached thereto by means of a screw
52 which passes through the cylinder 50 and into the threaded aperture 55
in set screw 48.
The bone line 70 is shown in FIG. 7 as being approximately mid-way through
the lower abutment casing 42, while the gum line 72 is just below the
upper edge of the outer or upper casing 44. Thus, the bone does not
interfere with the setting of the proper angle for the abutment and the
tissue is not likely to contact moveable adjustment parts.
The arrangement of FIG. 8 is a modification of that shown in FIG. 7. In
this arrangement the set screw 48, which has a threaded recess 55 at its
end in FIG. 7, is replaced with a set screw 49 that has a further screw
thread 59 on the opposite side of the hex projection 56. This additional
screw thread is used to mount an artificial tooth support cylinder 53
which has an interior threaded cavity. However, this device is essentially
located and fixed in position in the same manner as the implant of FIG. 7.
One difference with this implant of FIG. 8 is that the artificial tooth
support cylinder 53 may extend down to and in contact with the outer
casing 44. This is done above the gum tissue line 72 as shown in the
figure. Because of the contact between the cylinder and the casing 44,
food and bacteria are prevented from entering between these two parts and
the likelihood of infection is reduced. However, this arrangement allows
for somewhat less range of angular adjustment. In particular the
arrangement of FIG. 7 is capable of an angular adjustment range of
approximately 371/2, while that of FIG. 8 is limited to about 30.degree..
As a further alternative, the set screw 48, rather than having a projecting
threaded portion located above the hexagonal adjustment nut 56, may have a
projecting cylinder which is internally threaded (not shown). Thus either
a male or female connection of this type may be used without difficulty.
In order to get increased angular adjustment, an arrangement such as that
shown in FIG. 9 may be used. The abutment arrangement of FIG. 9 is
essentially the same as that of FIG. 7; however, the ball and socket joint
are made smaller and the ball sits higher in the socket joint. Further,
the set screw 54 of FIG. 9 is made to have a beveled surface 57 such that
a greater angular rotation may be made before it contacts the upper part
of the outer casing 44. With this arrangement nearly 45 degrees of angular
adjustment can be achieved.
The abutment cylinder 50 has a recess 51 to receive the outer end of the
set screw 54. This allows for greater stability when it is attached to the
set screw by means of attachment screw 52. The cylinder 50 is also angled
in the same manner as the surface 57 of the set screw 54 so that it does
not bind against the upper abutment casing 44 and limit angular rotation.
In FIG. 7-9 the ball rotates with the set screw during angular adjustment.
However, as an alternative, the ball may remain stationery and the
abutment casing may rotate as shown in FIG. 10. In FIG. 10 a threaded ball
joint 60 has a projecting threaded shaft 61 which is received in threaded
recess 19 of the implant portion 10. Various size protection washers or
collars 65 can be located about the finial part 67, which connects the
ball to the threaded shaft, in order to cover the upper surface of
whatever implant portion is used, thereby preventing bacteria and food
from entering the bore. The opening in the bone can be countersunk as
indicated by dotted line 70 so the collar can extend out beyond the
implant portion upper surface, and bone can grow over part of the upper
surface of the collar.
A two-part casing 62, 64 is mounted on the ball 60. The casing includes
outer casing portion 62, which secures the remote end of the ball, and an
inner casing 64, which provides the main hemispherical surface against
which the outer casing holds the ball in a rotatable manner. These two
casing parts can be threaded together or attached to each other in any
convenient manner. Their attachment, however, is such that the casing may
rotate freely on the ball.
At the opposite end of ball 60 from the screw threads is a hexagonal recess
63, which is the means by which this threaded ball joint is screwed into
the threaded recess 19 of the implant portion. In this arrangement the gum
line 72 is shown about 1/3 up from the base of the ball joint, but below
the lower extension of casing 62.
A hexagonal projection 66 is provided on the inner casing 64. This
projection can be used to rotate the inner casing 64 so that the ball is
squeezed between it and the outer casing 62 so that swiveling can be
prevented when the arrangement is at the proper angle. A conventional
cylinder 50 for a dental prosthesis is attached to the inner casing 64 by
means of a screw 52. This screw 52 penetrates a threaded aperture in the
inner casing.
An enlarged view of the inner casing 64 is shown in FIG. 11A. The lower
peripherial extension 64' of this casing forms a wedge that projects
between the ball 60 and the outer casing 62 as shown in FIG. 10. When the
inner casing 64 is screwed down onto ball 60, the extension 64' acts to
lock the abutment on the ball and prevents further rotation. In part this
locking is maintained due to the fact that the diameter of the extension
64' is slightly less that the distance across the ball at its location. As
a result there is an outward flaring of the extension as shown by the
arrows in FIG. 11A, which prevents the unthreading of inner casing 64.
Instead of a one piece casing as shown in FIG. 11A, the inner casing may be
in two parts as shown in FIG. 11B, where the extension 64' is part of a
locking ring or washer 64". With this arrangement the ball is surrounded
by the ring 64" and the casing 64. As the casing is threaded into contact
with the ball it forces the ring to wedge between the ball 60 and the
outer casing to frictionally hold the ball. The outward flaring of the
extension at the end of this compression process tends to prevent the
unthreading of the inner casing, which prevents the abutment from becoming
loose.
Installation of submergible implants is generally a two stage procedure.
During the first stage the implant portion is buried in the bone and the
tissue is restored in place over it. Time is allowed to pass while new
bone grows about, and often over, the implant. The tissue is then reopened
at the start of the second stage. If bone has grown over the submerged
implant, it must be removed by a burr before the abutment can be
installed. If the bone grows into the threaded aperture for the abutment,
however, removal of this bone may be very difficult. Consequently, it is
conventional to install a thread cap having a low height into the aperture
during the first stage. However, bone also grows over this cap and it must
be removed in order to replace the cap with the abutment. Removal of such
bone may cause some loosening of the implant portion.
With the present invention, the collar 65 is used with a screw 68 as a
temporary cap as shown in FIG. 12. Even if bone grows up over the edges of
the collar 65, there is no need to remove it because it becomes part of
the permanent abutment. In particular cover screw 68 is removed during the
second stage operation, which may require the removal of a small amount of
bone that has grown over the screw. Then the cover screw 68 is replaced
with threaded shaft of abutment ball 60 which has the abutment casings 62,
64 already installed. Thus the collar 65 which is anchored in bone, need
not be freed from the bone as in prior art caps, but becomes part of the
final abutment structure.
FIGS. 13 and 14 show front and side sectional views of an incisor of a
patient which is supported by an implant according to the present
invention. As can be seen, particularly from FIG. 14, the patient's upper
front jaw bone has only a thin amount of good bone 11 and this bone is at
an angle to the regular alignment of the other incisors in the patient's
mouth. Utilizing the present invention, implant portion 10 is located in
the center of the main portion of this bone. After this implant portion 10
is firmly anchored in good bone, either immediately after its insertion or
after several weeks or months have been allowed to pass, the abutment
portion is installed. The abutment portion is a ball and socket joint like
that in FIG. 7 having a set screw 48 which locks the ball 46 at the proper
angle. The cylinder 50 of the artificial tooth support is then attached to
the set screw via an attachment screw 52. As shown in cross section in
FIG. 14, cast metal 58 surrounds cylinder 50 and a porcelain or plastic
dental material 70 forms the tooth structure about the metal.
FIG. 15 illustrates a cross-sectional view of an abutment with
shock-absorbing capabilities. This abutment may be adapted for use with
any of the previously discussed implants and angular adjustment devices.
The abutment of FIG. 15 has a cylinder portion 70, upon which the
artificial tooth is mounted. In addition it has a collar 72. The cylinder
and collar are connected by a screw 74. Screw 74 also acts to connect the
cylinder and collar 70,72 to the rest of the abutment in much the same way
as screw 52 connects cylinder 50 to the rest of the implants in FIGS. 7, 9
and 10.
A flexible buna rubber washer 76, such as that used for over dentures, is
located between and separates the cylinder 70 and collar 72 so that the
cylinder 70 may move with respect to the collar 72. Typically, the
artificial tooth will be mounted only on the cylinder 70. As a result,
some of the forces applied to the artificial tooth during chewing or
biting are absorbed by the flexible washer 76 and are not transmitted to
the collar 72 and the rest of the implant.
In order to make it easy to install the washer 76, the cylinder and collar
parts are formed such that they define an oval recess which seats the
washer. The head 75 of the screw 74 and a peripheral flare 73 on the screw
tend to keep the washer within the oval recess.
During installation the washer is assembled between the cylinder 70 and
collar 72. Then the screw 74 is pushed down through the opening in the
cylinder part. The flare 73 compresses the washer 76 slightly as it passes
through the washer. Then the screw 74 is passed through collar 72 and
threaded into the rest of the implant. At some point, the flare 73 is
drawn against the opening in collar 72. However, the threading operation
is continued in order to wedge the flared part of screw 74 into collar 72.
This acts to keep screw 74 from unthreading after the artificial tooth is
put into use.
FIG. 16 shows an alternative version of the screw 74 of FIG. 15. In this
alternative, the flared part 73 has a triangular cross-sectional shape.
Once this screw has been pushed through the washer 76, it cannot be
withdrawn. Thus, it is necessary to cut the washer to remove it.
Besides being used to mount a single tooth, the implants according to the
present invention can be used as supports for a permanent bridge or a
removable bridge. In the case of a removable bridge the abutment cylinder
is in the form of small copings which can be spaced throughout the
edentulous span of a patient. These copings support a bar onto which the
bridge structure may be screwed or clipped.
While the invention has been particularly shown and described with
reference to preferred embodiments thereof, it will be understood by those
skilled in the art that various changes in form and details may be made
thereon without departing from the spirit and scope of the invention.
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