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Description  |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to an adjustable orthodontic bracket assembly,
adapted for use with an arch wire, wherein different sizes of arch wire
may be utilized and vector forces acting upon a tooth may be changed or
varied, all without removing the bracket assembly from the tooth being
treated.
2. Description of the Prior Art
In orthodontic practice, arch wire bending is a time consuming, but
essential component of the treatment procedure. Tooth alignment problems
are corrected by applying appropriate bends to a generally U-shaped arch
wire. When out-of-line, or malposed, teeth are secured to the arch wire by
means of orthodontic brackets, forces exerted upon the teeth to move them
into a desired orientation over a period of time to correct malocclusions
of the teeth. Teeth initially having proper alignment are secured to
unbent portions of the arch wire and may serve to define an "ideal"
orientation to which the other teeth are directed.
The modes of tooth movement required for correcting malocclusions of the
teeth include: up-down (elevating or lowering a tooth within its socket);
rotation (turning of the tooth in its socket about its longitudinal axis
either clockwise or counter clockwise); tipping (tilting of the tooth
toward the front, or mesially of the dental arch; or toward the back, or
distally of the dental arch); and torquing (twisting, or turning, the
tooth about an axis formed by the arch wire, either toward the tongue, or
lingual surface of the mouth, or toward the cheek or lip, or buccal or
labial surface of the mouth).
Present day orthodontic brackets are applied to the teeth by bonding the
bracket directly to the teeth. Each bracket is typically provided with a
slot for arch wire containment, or an arch wire receiving channel, and
ligature tie grooves, or wings, to receive elastic rings, or rubber bands,
or tie wires for securing the arch wire to each bracket. In older
techniques, the brackets were first welded to metal bands and the metal
bands were then slipped over the teeth and cemented into place. Present
one-piece orthodontic brackets are cast or molded to have a fixed,
predetermined amount of torque, tipping, and sometimes rotation designed
into the particular bracket. These brackets are designed to limit arch
wire bending somewhat for average, normally-shaped teeth, and it is
assumed that the bracket will be placed and bonded in a precisely
determined position upon the tooth. Since provision has only be made for
"average" teeth in these fixed, one-piece bracket systems, there is
typically no allowance for normally-occurring differences in tooth
anatomy, or in bracket placement errors. Bending of the arch wire is
therefore typically required to correct the alignment problems. In many
treatments, it may be necessary to remove the brackets from the teeth, and
rebond them in a different position; however, this can be a time consuming
process.
It has been proposed to provide multi-piece bracket systems, which
typically include a bracket and a bracket holder mounted upon the tooth,
as an attempt to eliminate some arch wire bending procedures, as well as
an attempt to avoid removal and rebonding of the bracket. A disadvantage
of such systems has been a large initial expense because the orthodontist
is required to purchase and maintain an inventory of a very large number
of specially slotted brackets. Furthermore, identification of the proper
bracket for each tooth and each situation is believed to be quite time
consuming. It is believed that such systems also suffer from the
disadvantage that it is typically necessary to remove the bracket from its
holder in a mesial-distal (side-to-side) movement, a difficult operation
particularly with small, closely positioned teeth. Some of these systems
also required that the orthodontist insert small pin members in order to
hold the multi-piece bracket systems together into their desired
configuration, which can also be a difficult and time consuming task.
A major disadvantage associated with both prior art one-piece or
multi-piece bracket assemblies has been that once the orthodontist begins
the orthodontic treatment and selects a particular size arch wire to use,
he must continue to use that particular arch wire throughout the treatment
procedure. If he decides to change the size of the arch wire, it is
necessary, in the case of one-piece brackets, to remove all of the
brackets from the teeth, and replace them with different brackets having a
larger arch wire slot, or arch wire receiving channel, in order to
accommodate the larger, or smaller, size arch wire. In this regard,
typically more force can be applied to the teeth when a larger arch wire
is used. In the case of multi-piece bracket assemblies, it would be
necessary to remove all of the brackets from the holders in order to
substitute different brackets having either a larger or a smaller size
slot, or arch wire receiving channel. Furthermore, in many of the
single-piece brackets, and multi-piece bracket assemblies, repeated
adjustments to the arch wire, and/or repeated substitution of bracket
pieces is required as the treatment progresses and the malposed teeth move
into their desired orientation.
An additional disadvantage associated with prior art orthodontic brackets
relates to the configuration of the slot, or arch wire receiving channel.
They are all typically formed as a generally U-shaped channel, having the
vertically extending legs joined to the base at right angles to one
another, and there are also right angles formed at the exit ends of the
channel. Thus, movement of the arch wire, whether caused by sliding
movement of the arch wire within the channel, or caused by bending of the
arch wire by the orthodontist, can cause the arch wire to bind within the
slot of the bracket at the sharp edges formed by the right angles.
Accordingly, prior to the development of the present invention, there has
been no adjustable orthodontic bracket assembly adapted for use with an
arch wire which: is simple and economical to use; permits different sizes
of arch wires to be utilized without either removing and rebonding the
bracket to the teeth or by changing all the bracket components of
multi-part systems; easily permits changing the vector forces acting upon
the teeth without removing the bracket or substituting an extensive number
of bracket components; and prevents binding of the arch wire within the
arch wire receiving channel, or slot. Therefore, the art has sought an
adjustable orthodontic bracket assembly, adapted for use with an arch
wire, which: is simple and economic to use; permits different sizes of
arch wires to be utilized in the orthodontic treatment, without removal
and rebonding of different sized brackets to the teeth, or without
substituting an entirely different size set of bracket members; permits
the vector forces exerted upon the teeth to be easily changed without
removing and rebonding brackets to the teeth, or without substituting an
excessive number of bracket components; and prevents binding of the arch
wire within the arch wire receiving channel.
SUMMARY OF THE INVENTION
In accordance with the invention, the foregoing advantages have been
achieved through the present adjustable bracket assembly, adapted for use
with an arch wire. The present invention includes: a base member having at
least one arch wire contact surface, the base member adapted to be
associated with the surface of a tooth; an attachment member having at
least one arch wire contact surface; and means for movably associating the
base member and the attachment member with respect to one another to
provide an arch wire receiving channel formed by the at least one arch
wire contact surfaces of the base member and the attachment member,
whereby the size of the arch wire receiving channel may be varied to
accommodate various sizes of arch wire. A feature of the present invention
is that the movable association means may include a sliding connection
means between the base member and the attachment member, and the sliding
connection means may include an opening disposed within the base member
and the attachment member has an elongate support member which is received
within the opening in a sliding relationship.
A further feature of the present invention is that it may include means for
biasing the base member and the attachment member together to bias the at
least one arch wire contact surfaces of the base member and the attachment
member into engagement with the arch wire. Another feature of the present
invention is that the base member and the attachment member may be
magnetized to provide the biasing means, whereby the base member and the
attachment member are biased toward one another by magnetic force.
Another feature of the present invention is that it may include a means for
releasably locking the base member and the attachment member together
while permitting the base member and the attachment member to move with
respect to one another, whereby the base member and the attachment member
are prevented from becoming accidentally disassociated while in use.
A further feature of the present invention is that it may include a means
for tipping the tooth to which the base member is associated, the tipping
means including two arch wire contact surfaces spaced apart from one
another and disposed on the attachment member, the two arch wire contact
surfaces lying in a plane which is not perpendicular with the longitudinal
axis of the attachment, whereby the tooth may be tipped about the at least
one arch wire contact surface of the base member and one contact surface
of the attachment member, until both arch wire contact surfaces of the
attachment member contact the arch wire.
An additional feature of the present invention is that it may be include
means for rotating the tooth to which the base member is associated, the
rotation means including at least one arch wire support slot disposed on
the attachment member and adjacent the at least one arch wire contact
surface, the arch wire support block adapted to contact the arch wire and
provide a fulcrum about which the tooth is rotated.
In accordance with the invention, the foregoing advantages have also been
achieved through the present method for forming a variable size arch wire
receiving channel in an orthodontic bracket assembly. The present
invention includes the steps of: providing at least one arch wire contact
surface upon a base member; providing at least one arch wire contact
surface upon an attachment member; and movably associating the base member
and the attachment member with respect to one another, whereby the at
least one arch wire contact surfaces of both the base member and the
attachment member may contact and engage the arch wire. A further feature
of the present invention is that the attachment and the base member may be
movably associated with respect to one another by slidably receiving a
portion of the attachment member within an opening formed in the base
member.
The adjustable orthodontic bracket assembly adapted for use with an arch
wire of the present invention, when compared with previously proposed
prior art orthodontic brackets and bracket assemblies, has the advantages
of: being simple and economical to use; permits different sizes of arch
wires to be used without removal and rebonding of the brackets to the
teeth; permits the vector forces applied to the teeth to be readily
changed without removal and rebonding of the brackets to the teeth; and
prevents binding of the arch wire within the arch wire receiving channel.
BRIEF DESCRIPTION OF THE DRAWINGS
In the Drawings:
FIG. 1 is a perspective view of an adjustable orthodontic bracket assembly
in accordance with the present invention;
FIG. 2 is a side view of the bracket assembly of FIG. 1;
FIG. 3 is a perspective view of a bracket assembly in accordance with the
present invention;
FIG. 4 is a partial perspective view of a portion of a bracket assembly in
accordance with the present invention;
FIG. 5 is a front view of two teeth having bracket assemblies in accordance
with the present invention bonded thereon, the teeth being shown at the
beginning of an orthodontic procedure;
FIG. 6 is a front view of the two teeth of FIG. 5 toward the end of the
orthodontic treatment;
FIG. 7 is a perspective view of four teeth having orthodontic bracket
assemblies in accordance with the present invention bonded thereon, the
teeth being shown at the beginning of an orthodontic treatment;
FIG. 8 is a perspective view of the teeth of FIG. 7 toward the end of the
orthodontic treatment;
FIG. 9 is a perspective view of an attachment member in accordance with the
present invention;
FIG. 10 is an exploded perspective view of a attachment member in
accordance with the present invention;
FIGS. 11 and 12 are front views of bracket assemblies in accordance with
the present invention; for tipping movement of teeth associated with the
bracket assemblies;
FIG. 13 is a perspective view of a bracket assembly in accordance with the
present invention when a buccal tube is provided; and
FIG. 14 is a side view of the bracket assembly of FIG. 13.
While the invention will be described in connection with the preferred
embodiment, it will be understood that it is not intended to limit the
invention to that embodiment. On the contrary, it is intended to cover all
alternatives, modifications, and equivalents, as may be included within
the spirit and scope of the invention as defined by the appended claims.
DETAILED DESCRIPTION OF THE INVENTION
With reference to FIGS. 1-3, an adjustable orthodontic bracket assembly 150
adapted for use with an arch wire 151, in accordance with the present
invention, is shown to generally comprise a base member 152; an attachment
member 153; and means for movably associating 154 base member 152 and the
attachment member 153 to one another to provide an arch wire receiving
channel 155. Base member 152 has at least one arch wire contact surface
156 associated therewith, and the base member 152 is adapted to be
associated with the surface of a tooth 157 (phantom lines in FIG. 2) in a
conventional manner. In this regard, base member 152 may include a
mounting base 158 with any suitable configuration which may be bonded in a
conventional manner to the surface of tooth 157. Preferably, mounting base
158 has an oval configuration so as to provide smooth rounded surfaces for
comfort for the wearer and for ease of cleaning. As is conventional in the
art, base member 152, as well as attachment member 153, may be made from
any suitable material used for orthodontic brackets and appliances, such
as stainless steel or any plastic material having the requisite strength
characteristics. As will hereinafter be apparent to one of ordinary skill
in the art, the adjustable orthodontic bracket assembly 150 in accordance
with the present invention, may also be associated with a tooth, such as
tooth 157, as by securing mounting base 158 to conventional bands (not
shown) which are cemented to the teeth.
Still with reference to FIGS. 1-3, attachment member 153 also has at least
one arch wire contact surface 159 associated therewith. As will
hereinafter be described in further detail, the embodiment of orthodontic
bracket assembly 150 of FIG. 3 has two arch wire contact surfaces 159 and
160 associated with attachment member 153. As seen in FIG. 1, after base
member 152 and attachment member 153 have been movably associated with
respect to one another, as will hereinafter be described in greater
detail, arch wire receiving channel 155 is formed by the at least one arch
wire contact surface 156 of base member 152 and the at least one arch wire
contact surface 159 (FIGS. 1 and 2) or 159,160 (FIG. 3). The movable
association means 154 includes a sliding connection means 161 between the
base 152 and the attachment member 153, wherein the sliding connection
member means 161 includes an opening 162 disposed within the base member
152, and the attachment member 153 has an elongate support member 163
which is received within the opening 162 in a sliding relationship.
The elongate support member 163 of attachment member 153 preferably has a
generally rectangular cross-sectional configuration having an upper end
164 having a rounded configuration as seen in FIGS. 1 and 3. Opening 162
in turn has the same generally rectangular cross-sectional configuration
as that of the elongate support member 163 of attachment member 153,
whereby the elongate support member 163 is slidable within opening 162, as
well as guided within opening 162 by the wall surface 165 of base member
152 which forms opening 162. It should be apparent to one skilled in the
art, that other cross-sectional configurations for elongate support member
163 and for the mating of opening 162 could be utilized in practicing the
present invention.
Because of the sliding connection means 161 of the movable association
means 154, different sizes of arch wire 151 can be accommodated within the
arch wire receiving channel 155 of bracket assembly 150. Attachment member
153 may be moved with respect to base member 152 to either decrease the
distance between arch wire contact surfaces 156 and 159 (or 159,160 as
shown in FIG. 3) or to slide attachment member 153 downwardly to increase
the distance between the arch wire contact surfaces 156 and 159 (or
159,160 in FIG. 3). Thus, if an orthodontist decides to change the size of
the arch wire 151 being utilized in a particular orthodontic treatment, it
is unnecessary to remove base member 152 from tooth 157, nor is it
necessary for the orthodontist to remove and replace attachment member
153, in order to accommodate either a larger or smaller arch wire 151.
Still with reference to FIGS. 1-3, orthodontic bracket assembly 150 may be
provided with a means for biasing 168 the base member 152 and the
attachment member 153 together to bias the at least one arch wire contact
surfaces 156,159,160 of the base member 152 and attachment member 153 into
engagement with the arch wire 151. Conventional elastic bands, or rubber
bands, 169 (FIGS. 1-2 in phantom lines) may be utilized as the biasing
means 168. The attachment member 153 and base member 152 may each be
provided with wing members 170,171 associated therewith for engagement
with the rubber band 169 in a conventional manner. Alternatively, base
member 152 and attachment member 153 may be manufactured of a magnetic
material, and/or magnetized, to provide the biasing means 168, whereby the
base member 152 and the attachment member 153 are biased toward each other
by the magnetic force of the magnetic material or the magnetic attraction
forces between the base member 152 and attachment member 153. It should be
noted that it is preferable that all the surfaces of the base member 152
and attachment member 153, including wing members 170,171 have a smooth
rounded configuration so as to minimize any discomfort to the orthodontic
patient.
With reference to FIGS. 1-4, orthodontic bracket assembly 150 of the
present invention may include a means for releasably locking 175 the base
member 152 and the attachment member 153 together while permitting the
base member 152 and the attachment member 153 to move with respect to one
another, whereby the base member 152 and the attachment member 153 are
prevented from becoming accidentally disassociated while in use. For
example, were a rubber band 169 to be used for the biasing means 168, and
the rubber band 169 were to break, it would be possible that attachment
member 153 could slide outwardly from base member 152, and either remain
dangling from base member 152 or perhaps completely becoming disengaged
therefrom. Releasable locking means 175 may be thus provided to the
orthodontic bracket assembly 150. Releasable locking means 175, as seen in
FIGS. 1-3, may include at least one projection member 176 disposed on
attachment member 153 and engageable with the base member 152 to prevent
the accidental disassociation of the base member 152 and the attachment
member 153. The at least one projection member 176 of FIGS. 1-3 may be
disposed upon the elongate support member 163 of attachment member 153,
and the projection member 176 may have a rounded configuration which
protrudes beyond the outer surface of elongate support member 163 and
slightly beyond the opening 162 in base member 152. When it is desired to
initially assemble bracket assembly 150 by inserting attachment member 153
within base member 152, there is sufficient yielding between attachment
member 153 and base member 152, whereby the projection member 176 may be
slightly compressed and pass through opening 162 of base member 152 and in
turn pass wing 171 of base member 152, upon the application of sufficient
force by the orthodontist. Were rubber band 169 to break, it is possible
that attachment member 153 might slide downwardly, when viewed in FIG. 2;
however, it is envisioned that an insufficient force would be exerted upon
attachment member 153 to cause the projection member 176 to move past
either wing 171 or through opening 162.
In FIG. 4, another embodiment of projection member 176 of locking means 175
is shown to comprise at least one, and preferably two tapered wedge
members 176' which, upon the application of a sufficient force by the
orthodontist, may pass through opening 162 and pass wall surface 165 of
base member 152. Should biasing rubber band 169 break, it is believed that
an insufficient force would be exerted upon the elongate support member
163, whereby the wedge members, or projection members, 176' would not pass
through opening 162 in base member 152.
As seen in FIGS. 1-4, the arch wire contact surfaces 156,159,160, all have
a rounded configuration 179. As seen in FIG. 1, when arch wire 151 is
moved to the left or right is shown by arrows 180, arch wire 151 would not
contact, nor engage, all of the arch wire contact surface 156 or 159, but
rather would make point contact such as with line 180 of arch wire contact
surface 159. Likewise, should arch wire 151 move in the direction shown by
arrows 181, sliding movement of attachment member 153 with respect to base
member 152 would accommodate movement of arch wire 151 in the direction of
arrows 181, and arch wire 151 would likewise not contact the entire arch
wire contact surface 156,159, although the surface area of arch wire
contact surfaces 156 and 159 contacted by arch wire 151 would increase
somewhat from that illustrated by line 181 of FIG. 1. Furthermore, as arch
wire moves upwardly and downwardly in the direction shown by arrows 181,
there are no sharp edges, such as right angle edges found in the prior
art, which would grip, or bind, arch wire 151 within arch wire receiving
channel 155.
With reference to FIG. 2, the orthodontic bracket assembly 150 may be
provided with a means for torquing 185 the tooth 157 to which the base 152
is associated. As previously described, torquing of a tooth is twisting or
turning of the tooth about an axis formed by the arch wire 151, or
movement in the direction of arrows 186 in FIG. 2. Torquing means 185 may
be provided by using an inclined surface 187 as at least one arch wire
contact surface, which is preferably the arch wire contact surface 159'
disposed upon attachment member 153. Because of the inclined surface 187
and its point contact with arch wire 151, bracket 150 may pivot about the
point contact between arch wire 151 and the inclined surface 187 in the
direction of arrows 186, dependent upon the forces acting upon bracket
150, which forces may be applied as by conventional ligature wires or
rubber bands 169, attached to attachment member 153.
When bracket assembly is provided with torquing means 185, the arch wire
contact surface 159', or inclined surface 187 (FIG. 2), is utilized. Arch
wire contact surface 159' when viewed in the direction shown by arrow 188
in FIG. 1 would have the same rounded configuration 179 of arch wire
contact surface 159 previously described, but the arch wire contact
surface 159' would only lie in a plane as illustrated by phantom line 187,
when viewed from the side as in FIG. 2.
The bracket assemblies 150 of FIGS. 1 and 3 are generally used for
providing upward or downward movement of tooth 157 as will be hereinafter
described in further detail with reference to FIGS. 5 and 6. Bracket
assembly 150 of FIG. 2, when provided with torquing means 185, may be
utilized to provide both upward or downward movement of tooth 157, as well
as the torquing movement in the direction of arrows 186 as previously
described. The embodiment of bracket assembly 150 of FIGS. 1-3 may also be
utilized to provide rotation of tooth 157. Such rotation may be provided
by disposing a shim or elastic band 190 (FIG. 2 in phantom lines) over
wing members 170,171 and disposing the shim or elastic band 190 between
the elongate support member 163 of attachment member 153 and the arch wire
151, with the rubber band 169 being used as biasing means 168 in the
position shown in FIG. 2. Thus, the elastic band 190, or shim, permits
tooth 157 to be rotated with respect to arch wire 151 about an axis formed
by the longitudinal axis of elongate support member 163 of attachment
member 153. As will be hereinafter further described in connection with
FIG. 9, another manner in which to rotate tooth 157 will be described.
With reference now to FIGS. 5-6 and 11-12, a means for tipping 200 a tooth
to which a base member 152 is associated will be described. In FIG. 5,
tooth 157 is shown with the base member 152 and attachment member 153, as
previously described in connection with FIG. 3, attached thereto. Biasing
means 168 or rubber band 169 is utilized, and as seen in FIG. 6, upon
completion of the orthodontic treatment, tooth 157 has been raised in the
direction of arrow 201 to assume the position shown in FIG. 6. Tooth 202
of FIG. 5 is desired to be moved in the direction of arrow 203, or tipped
in the direction of arrow 203 by the orthodontist. Means for tipping 200
tooth 202 includes two arch wire contact surfaces 159,160, as previously
described in connection with FIG. 3, the two arch wire contact surfaces
159,160 being spaced apart from one another and disposed on the attachment
member 153, as by connecting them to elongate support member 163 of
attachment member 153, as previously described in connection with FIG. 3.
The arch wire contact surfaces 159,160 of the bracket assembly 150 in FIG.
5 differ from those shown in FIG. 3 in that arch wire contact surfaces
159,160 lie in a plane 204 (phantom lines in FIG. 5 and as shown in FIGS.
11 and 12) which is not perpendicular with the longitudinal axis 205 of
attachment member 153. Upon a biasing force being applied upon attachment
member 153 and base member 152 as shown in FIG. 5, tooth 202 will pivot
about arch wire contact surface 159 until tooth 202 assumes the
orientation shown in FIG. 6, wherein both arch wire contact surfaces of
attachment member 153 contact arch wire 151, as also seen in FIG. 11.
With reference to FIGS. 7 and 8, it is seen that it is desired to raise
tooth 157 from position shown in FIG. 7 to that shown in FIG. 8, and it is
desired to tip tooth 202 in the direction shown by arrow 203 into the
position shown in FIG. 8. Likewise, it is desired to tip tooth 210 from
the position shown in FIG. 7 to the position shown in FIG. 8. Tooth 210 is
provided with a bracket assembly 150 having tipping means 200 wherein arch
wire contact surfaces 160 and 159 are also disposed in the plane 204 which
is not perpendicular with the longitudinal axis 205 of attachment member
153 as seen in FIGS. 7 and 12; however, in the case of the bracket
assembly 150 associated with tooth 210, arch wire contact surface 160 is
initially in contact with arch wire 151. After the biasing force has been
applied, arch wire contact surface 159 of bracket assembly 150 will also
contact arch wire 151, as shown in FIGS. 8 and 12. In FIGS. 7 and 8, tooth
220 is a molar, whereby it can be seen that through use of tipping means
202, it is possible to tip a tooth, such as tooth 201 mesially in the
direction of arrow 203?, as well as to tip a tooth, such as tooth 210
distally as in the direction of arrow 204. As will be described in further
detail in connection with FIGS. 13 and 14, molar 220 is provided with
another embodiment of bracket assembly 150 which forms a buccal tube as
will hereinafter be described in further detail.
With reference to FIG. 10, another tipping means 200' is illustrated.
Whereas the tipping means 200 is shown in FIGS. 5-7 and 11-12 utilizes two
arch wire contact surfaces which are fixedly secured to the attachment
member 153, in FIG. 10 the two arch wire contact surfaces 159,160 are
adjustably mounted on the attachment member 153. As seen in FIG. 10,
elongate support member 163 is provided with an opening 230, and arch wire
contact surfaces 159,160 (arch wire contact surface 159 being shown in
phantom lines) are disposed apart from another via a connector member 231
having an opening 232 form therein. The lower end of elongate support
member 163 has a tension wire, or spring, 233 having its lower end 234
fixedly secured to the lower end of elongate support member 163. The upper
end 235 of tension wire, or spring, 233 is spaced outwardly from elongate
support member 163. Connector member 231 is then disposed between the
upper end 235 of tension wire spring 233 and elongate support member 163,
with opening 232 of connector member 231 in a mating relationship with
opening 230 of elongate support member 163. A pin or screw connector 236
may then be passed through openings 232 into opening 230 to secure
connector member 231 to elongate support member 163. The upper end 235 of
tension wire, or spring, 233 may then be engageable with a plurality of
slotted grooves 237 formed in connector member 231. By turning the
connector member 231 with arch wire contact surfaces 159,160 attached
thereto, about pin 236, the upper end 235 of tension wire or spring 233
will mate with one of the grooves 237, whereby arch wire contact surfaces
may assume the positions shown in FIGS. 11, 12, or 3, dependent upon which
groove the upper end 235 of tension wire or spring 233 is disposed.
With reference now to FIG. 9, a means for rotating 240 a tooth to which a
base member 152 (FIG. 3) is associated, is illustrated. Attachment member
153 of FIG. 9 is identical to that previously described in connection with
FIG. 3 and is used with the same base member 152 as previously described
in connection with FIGS. 1-8 and 10-12, with the exception that base
member 153 is provided with rotation means 240. Rotation means 240
includes at least one arch wire support block 241,242 disposed on
attachment member 153 and adjacent the at least one arch wire contact
surface 159,160. The arch wire support blocks 241,242 may be fixedly
secured to attachment member 153 as by a cross member 245 fixedly secured
to the elongate support member 163 of attachment member 153. When the
attachment member 153 of FIG. 9, having rotation means 240 associated
therewith, is disposed on base member 152, arch wire 151 will abut and
contact the arch wire support blocks 241,242, which in turn provides a
fulcrum for the tooth to be rotated about its longitudinal axis. If a
single arch wire support block 241 is utilized as the rotation means 240,
this arch wire support block 241 would contact the arch wire 151, upon
application of a biasing force, such as by a rubber band connecting end
246 of cross member 245 to arch wire 151. That biasing force will cause
the tooth to rotate about the contact point between arch wire support
block 241 and arch wire 151, or in other words will cause the tooth to be
rotated about its longitudinal axis, which would generally correspond to
the longitudinal axis of the attachment member 153. If two arch wire
support blocks 241,242 were utilized as the rotation means 240, each arch
wire support block would have a groove 247,248 formed therein to matingly
receive arch wire 151. The depth of the two grooves 247,248 would differ
whereby at the beginning of the treatment, the arch wire would only be in
contact with the bottom of one of the grooves, the other groove bottom
being spaced from the arch wire. After application of a biasing force upon
attachment member 153, the tooth will be rotated whereby both groove
bottoms would be in contact with arch wire 151. For example, if the groove
248 of arch wire support block 242 were deeper than the groove 247 of arch
wire support block 241, only the bottom of groove 247 of arch wire support
block 241 would contact arch wire 151. Upon application of a biasing
force, upon the end 246 of cross member 245, a tooth associated with
attachment member 153 of FIG. 9 would be rotated in the direction shown by
arrow 249. Rotation in the opposite direction from arrow 249 could be
achieved by reversing the arch wire support blocks 241,242. It should be
noted that the rotation means 240 illustrated in FIG. 9 could be combined
with tipping means 200, by disposing arch wire contact surfaces 159,160 in
a plane which is not perpendicular with the longitudinal axis of the
attachment member 153 as previously described in connection with FIGS. 5-8
and 10-12.
With reference now to FIGS. 13 and 14, a buccal tube 260 embodiment of
bracket assembly 150' is illustrated. A base member 152' is provided which
has two arch wire contact surfaces 159' associated with mounting base
158'. Mounting base 158' differs from mounting base 158 previously
described in that it is wider to accommodate the two arch wire contact
surfaces 156'. Arch wire contact surfaces 159' differ from those
previously described in connection with FIG. 1, in that arch wire contact
surfaces 159' do not have a rounded configuration, but rather a flat
planer configuration 261, as found in conventional buccal tubes. Bracket
assembly 150' is provided with two attachment member 153' as previously
described in connection with FIG. 1, with the exception that arch wire
contact surfaces 159' have the same configuration as contact surfaces 156'
as previously described. If desired, the two attachment members 153' could
be joined by a connector member 262 as shown in phantom lines in FIG. 13
to provide additional strength and rigidity. Each arch wire contact
surface 159' and 156' is provided with enclosure member 263 disposed
adjacent each arch wire contact surface. As seen in FIGS. 13 and 14,
biasing means 168 or rubber bands 169 cause the attachment members 153' to
move into an abutting relationship with the base member 152' whereby the
closure members 267 of the attachment member 153' abut the closure members
267 of the base member 152' to form a buccal tube 260 which receives the
arch wire 151 therein. As is conventional in the art, buccal tubes 260 are
typically provided upon molars, such as molar 220 (FIGS. 7 and 8).
In accordance with the invention, as previously described, a method for
forming a variable sized arch wire receiving channel 155 in an orthodontic
bracket assembly 150 comprises the steps of: (a) providing at least one
arch wire contact surface 156 upon a base member 152; (b) providing at
least one arch wire contact surface 159 upon attachment member 153; and
(c) movably associating the base member 152 and the attachment member 153
with respect to one another, whereby the at least one arch wire contact
surfaces 156,159 of the base member 152 and the attachment member 153 may
contact and engage the arch wire 151. As previously described, a further
step of the method in accordance with the present invention is movably
associating the attachment member 153 and the base member 152 with respect
to one another by slidably receiving a portion of the attachment member
153, such as elongate support arm 163, within an opening 162 formed in the
base member 152.
It should be noted that in beginning an orthodontic treatment with the
adjustable orthodontic bracket assembly 150 of the present invention, a
base member may be initially bonded to all the teeth, but it is not
necessary to use an attachment member in connection with each base member.
For example, initially there may be a tooth which is disposed so far away
from the arch wire that an attachment member would not reach the
particular base member with which it should be associated. With the
adjustable orthodontic bracket assembly of the present invention, the
attachment member 153 can be deleted and a biasing means, or rubber band,
can be stretched between the base member and the arch wire, or between the
base member and an adjacent tooth to initially move the malposed tooth
into its proper orientation. While the attachment is not being utilized,
it does not interfere with the treatment of adjacent teeth, and after the
malposed tooth has moved toward its desired orientation, an attachment
member can be later associated with the base member in the manner
previously described herein.
It is to be understood that the invention is not limited to the exact
details of construction, operation, exact materials, or embodiment shown
and described, as obvious modifications and equivalents will be apparent
to one skilled in the art. For example, while the adjustable orthodontic
bracket assembly of the present invention has been illustrated for use on
the labial and buccal surfaces of the teeth, the bracket assembly of the
present invention could be used on the lingual surfaces of the teeth.
Accordingly, the invention is therefore to be limited only by the scope of
the appended claims.
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