Patent Grant
8177557
This invention relates generally to a dental bridge, insert or other dental device and, more particularly, to framework for use in producing tooth-replacement bridges, reconstructing one or more teeth or splinting one or more unstable teeth.
In some independent aspects and in some constructions, an adjustable system for bonded composites may generally include a ladder supporting a truss in one of multiple relative positions therewith. The ladder generally includes opposing rails connected by a plurality of rungs. The plurality of rungs are spaced along the rails to define a plurality of openings between adjacent rungs. The truss generally includes a strip, which may be formed of metal or another material, having a plurality of upstanding projections. The projections are correspondingly spaced with the openings defined in the ladder to allow the truss to engage the ladder in a plurality of relative configurations. The combination of the ladder and truss may also provide a torsionally rigid and substantially stiff assembly with which to support one or more pontics and/or unstable teeth.
In some independent aspects and in some constructions, a system for bonded composites may generally include a reinforced substructure for supporting a pontic. The reinforced substructure, which may be formed of metal or another material, may be substantially webbed or generally include a plurality of apertures or perforations therethrough to allow the flow or seepage of resin through and around the substructure for increased bonding strength of the resin between the pontic and the substructure. The substructure also generally includes reinforcing structure or framework in a direction along the ladder and truss, to which the substructure is coupled, and in a direction substantially normal to the ladder and truss.
In some independent aspects and in some constructions, a system for bonded composites may generally include the ladder and truss structure having a sufficient length to extend substantially through one or more teeth and a plurality of apertures or perforations therein to allow the flow or seepage of resin through and around the ladder and truss for increased bonding strength of the resin between the supporting one or more teeth and the ladder and truss.
In some independent aspects and in some constructions, a system for bonded composites may generally include provisions for occlusal stops. One or more projections on the truss may be configured to extend sufficiently far through the ladder such that the one or more projections serve to slow or halt the occlusal wear of the pontic and/or of adjacent teeth.
In some independent aspects and in some constructions, a system for bonded composites may generally include a bendable ladder structure configured to go through a quadrant of teeth, a half-arch of teeth, or a full arch of teeth. The ladder structure may also be configured with an anterior segment for full or partial arch splinting. The anterior segment may include a single rail connecting ladder structures at opposite ends thereof, in addition to a plurality of apertures or perforations therethrough to allow the flow or seepage of resin through and around the ladder and truss for increased bonding strength of the resin between the supporting one or more teeth and the anterior segment. In addition, the bendable ladder structure may support a relatively long span of teeth or other attachments (e.g., arch wires).
In some independent aspects and in some constructions, a system for bonded composites may generally include a ladder and truss structure adaptable by the dentist and/or oral surgeon while sitting chair side with their patients. The adjustability built into the ladder and truss structure allows the dentist and/or oral surgeon to make adjustments to the composite without having to send it off-site to a laboratory.
In some independent aspects and in some constructions, a dental device may include a structural portion extending along an axis and connectable to at least one tooth. A truss portion may depend from the structural portion and be operable to support a pontic, the truss portion having a peripheral surface, the truss portion defining a plurality of slots, each of the slots extending from the peripheral surface. Each of the slots may extend parallel to the axis. The structural portion may have a first surface oriented toward the occlusal surface and an opposite second surface, the structural portion defining a plurality of openings, the plurality of openings extending transverse to the axis and between the first surface and the second surface. The structural portion may define an angled surface leading into at least one of the plurality of openings. A plurality of projections may be formed on a first surface of the structural portion, each of the projections having a projection surface spaced beyond the first surface toward the occlusal surface.
In some constructions, the dental device includes a dental bridge. In some constructions, the dental device includes an insert for one or more teeth.
In some independent aspects and in some constructions, a method of manufacturing a prefabricated dental bridge may be provided. The method may generally include forming a unitary dental bridge framework connectable to at least two abutment teeth, each abutment tooth having a tooth occlusal surface, and forming a pontic on the dental bridge framework.
Forming the unitary dental bridge framework may include forming a structural portion extending along an axis and having a width transverse to the axis and a length along the axis, the length being greater than the width, the structural portion having a first end and an opposite, second end, the first end being connectable to one abutment tooth and the second end being connectable to another abutment tooth, the structural portion having a first surface oriented toward the tooth occlusal surface and an opposite, second surface, and forming a truss portion integrally with the structural portion and depending from the second surface of the structural portion, the truss portion being positioned along the length of the structural portion spaced from the first end and from the second end, a first portion of the length of the structural portion being defined between the truss portion and the first end and a second portion of the length of the structural portion being defined between the truss portion and the second end.
Forming the unitary dental bridge framework may also include forming a first slot in the first portion of the length, the first slot extending along the axis and from the second surface toward the first surface, the first slot having opposite side walls, forming a second slot in the second portion of the length, the second slot extending along the axis and from the second surface toward the first surface, the second slot having opposite side walls, and forming a plurality of openings extending through the structural portion transverse to the axis and from the first surface toward the second surface, the plurality of openings being spaced from the truss portion along the length of the structural portion, at least one of the plurality of openings being formed in the first portion of the length of the structural portion, at least another of the plurality of openings being formed in the second portion of the length of the structural portion.
In some independent aspects and in some constructions, a method of installing a prefabricated dental bridge may be provided. The method may generally include, prior to a dentist examining a patient, manufacturing the prefabricated dental bridge, manufacturing including forming a unitary dental bridge framework including forming a structural portion extending along an axis, and forming a truss portion integrally with the structural portion, the truss portion depending from the structural portion, and forming a tooth-shaped pontic on the dental bridge framework. The method may also include providing the prefabricated dental bridge to the dentist, examining the patient, preparing at least two abutment teeth of the patient, positioning the dental bridge on the abutment teeth, and bonding the dental bridge to the abutment teeth.
In some independent aspects and in some constructions, a prefabricated dental bridge may generally include a unitary dental bridge framework connectable to at least two abutment teeth, the unitary dental bridge framework including a structural portion extending along an axis, and a truss portion integrally formed with the structural portion and depending from the structural portion; and a tooth-shaped pontic formed on the dental bridge framework.
Independent features and independent advantages of the present invention will become apparent to those skilled in the art upon review of the following detailed description, claims and drawings.
a is an enlarged perspective view illustrating the connection between the anterior arch wire shown in
b is a perspective view of the combination of the anterior arch wire shown in
a is an exploded view of the assembly shown in
b is a perspective view of the assembly of
a is a perspective view of the assembly shown in
b is a perspective view of the assembly shown in
a is a perspective view of the assembly shown in
a is a perspective view of another arrangement of a bridge with two reinforcing structures adjacent to one another, the middle reinforcing structure coupled to a pontic partially filled with composite resin and adjacent to a tooth.
a is an exploded view of the assembly shown in
b is an exploded view of another construction of the reinforcing structure, with a substructure coupled to a bridge.
c is an assembled view of the construction shown in
d is an assembled view of the construction shown in
a-25c are views of the insert shown in
a is a perspective view of the insert shown in
b is a perspective view of the insert bonded to a quarter of a pontic shown in
c is a perspective view of the insert bonded to a quarter of a pontic shown in
a are views of a bridge with a reinforcing structure of
Before any independent features and at least one construction of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of the components set forth in the following description or illustrated in the drawings. The invention is capable of other constructions and of being practiced or being carried out in various ways. Also, it is understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including”, “having” and “comprising” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items.
Although references may be made below to directions, such as upper, lower, downward, upward, rearward, bottom, front, rear, etc., in describing the drawings, these references are made relative to the drawings (as normally viewed) for convenience. These directions are not intended to be taken literally or limit the present invention in any form. In addition, terms such as “first” and “second” are used herein for purposes of description and are not intended to indicate or imply relative importance or significance.
In some independent aspects and in some constructions, an adjustable system for bonded composite dentistry may be provided. The system for bonded composites generally includes multiple parts that can be altered and used alone or in combination to perform a plurality of operations such as, for example, splinting one or more unstable teeth, reconstructing one or more teeth, supporting pontics, bridging gaps between teeth, preventing additional wear on new or existing teeth, etc.
As described below in more detail, in some constructions, a dental device, such as a prefabricated dental bridge, may generally include an oversized composite resin pontic molded onto a prefabricated (e.g., medical-grade titanium) framework which may feature occlusal stops/projections alternating with occlusal perforations/openings. One or two teeth on either side of an edentulous space are prepared with MOD, MO, or DO preps, and the dental bridge is then shaped to fit the preps and edentulous space. During installation, composite resin flows both around the structural portion and into and through the occlusal perforations. When light cured, the composite resin mechanically and chemically locks the bridge in place.
The dental device may be a prefabricated, mass produced dental bridge which is oversized in both length and pontic size so that it can be reduced in size and installed by a dentist to fit any appropriate patient in one visit. The illustrated dental devices may provide a minimally invasive, structurally sound, low-cost alternative to implants, one-tooth partials, Maryland bridges and other conventional fixed bridgework. The shaping and adapting of the illustrated dental devices can be accomplished chair side (direct method) or in the office lab using a quick set stone or plaster model from an impression of the appropriate quadrant (indirect method).
As shown in
In the illustrated construction, the rails 12 each include a plurality of apertures or perforations 16 therethrough. The apertures 16 can be round and are distributed along the ladder 10 to, for example, allow for the flow of composite resin. In the illustrated construction, the rails 12 are configured such that they are separable from one another so a segment comprising a singular rail may be formed, if desired, as part of the overall framework of the ladder 10.
The plurality of rungs 14 are spaced along the rails 12 to define a plurality of openings 18 between adjacent rungs 14. The rungs 14 may be hollow or solid. The rungs 14 may have various cross-sectional shapes such as, for example, round, oval or square.
With reference to
In the illustrated construction, the truss 20 includes a strip 22 having a plurality of upstanding projections 24. The projections 24 may act as occlusal stops and to protect the biting portion of bonded teeth from the wear that occurs through mastication and contact with the opposite set of teeth. The projections 24 of the truss 20 are correspondingly spaced with the openings 18 defined in the ladder 10 to allow the truss 20 to engage the ladder 10 in a plurality of relative configurations to yield a bridge. One or more apertures 26 may also be formed through the truss 20 in a location between the projections 24.
The projections 24 may be arranged on the truss 20 to engage in the opening 18 between every, every other, every third or every fourth rung 14 in the ladder 10. As a result, the truss 20 may fit precisely between the two rails 12, and the projections 24 may fit precisely in the opening 18 between every, every other, every third, or every fourth rung 14 in the ladder 10 to interlock the truss 20 and ladder 10. In addition, the projections 24 may act as occlusal stops by extending above the ladder 10 (e.g., ending 1-1.5 mm above the height of the top portion of the rails 12 and rungs 14). The truss 20, after interlocking with the ladder 10, reinforces and/or bridges the openings or open span between the rungs 14 on the ladder 10.
The substructure 28 can be connected to a cross truss 32, as shown in
One or more portions of the truss 20 (e.g., the strip 22, the projections 24, the substructure 28, the cross truss 32, etc.) may be formed of metal. In the illustrated construction, the structures of the truss 20 are formed of metal. In other constructions, one or more of the structures of the truss 20 may be formed of another material, such as, for example, a composite material.
With reference to
As illustrated in
With reference to
Adding a shield 42 to the combination of the segment 36, bridge 35, and reinforcing structure 34 of
In the illustrated construction, the arch wire 48 is a solid wire as opposed to the segment 36 with perforations 40. The arch wire 48 can have a variety of applications including, for example, supporting anterior teeth that may be loose or maintaining alignment of anterior teeth. The arch wire 48 can be bonded to the back of a row of teeth, as understood in the art.
a show the bridge 35 and the reinforcing structure 34 during the process of inserting a pontic 64 onto the reinforcing structure 34. Pontics 64 used with the illustrated constructions of the bridge 35 can have various sizes. The pontic 64 illustrated in
With reference to
a-20d show a bridge 72 with reinforcing structure 34. The ladder 10 and truss 20 are merged into a one piece flat plane bridge 72. The bridge 72 may be made, for example, by casting or another method, of an appropriate material, such as, for example, gold, titanium, laboratory processed composite, etc. The bridge 72 is imbedded into unpolymerized composite resin, and then the resin is tamped over and light-polymerized or cured. Thus, the bridge 72 will form the contact points, the marginal ridges, and the occlusal stops of a bonded, composite restoration.
As shown in
In some independent aspects, a system for making and installing a temporary bridge, in which the dentist makes the temporary bridge chair side, is provided. The dentist first selects the appropriate length of the ladder 10 and snaps in a section of the truss 20 with one, two, three, or more reinforcing structures 34 depending on how many teeth are missing.
The dentist can select a reinforcement 70 that slides into the side apertures or perforations 16 in the rails 12. The fingers 66 sit lingual to the prepared teeth (e.g., molar, bicuspid, cuspid, lateral, and central), and the dentist sets a small amount of unpolymerized light-cured composite on the occlusal surface of the prepared teeth.
The dentist places the ladder 10, truss 20, and one or more reinforcing structures 34 into the unpolymerized light-cured composite. The dentist partially light-cures the resin without bonding the resin to the tooth. The dentist takes a vacuum-formed clear stent and fills it with acrylic or composite, then sets it over the ladder 10 and truss 20 on the prepared teeth, so that when the temporary bridge is removed, the ladder 10, truss 20, and pontic(s) are picked up because they are internally incorporated in the temporary bridge. The projections 24 on the truss 20 act as occlusal stops to prevent the wearing of the bridge. The temporary bridge is both reinforced and slow to wear occlusally to provide a long-term temporary bridge.
In contrast, in conventional dental bridges, the laboratory fashions the temporary bridge in a different manner. After receiving the study models and bite from the dentist, the laboratory prepares the designated teeth for crown preps. The laboratory selects the appropriate length and pontic size for the bridge and appropriate lingual reinforcement systems. The laboratory constructs the reinforced temporary bridge for placement by the dentist into the patient's mouth.
In some aspects, the system may eliminate any casting to be done because the individual components (e.g., the ladder 10, truss 20, substructure 28, etc.) can be a part of an extensive kit available to the dentist. For the reinforced single, double, or more pontic bridge, all the dentist has to do is send the laboratory a set of unprepared study models, a bite, and a shade. The laboratory can groove the MO, DO, MOD preps in the adjacent teeth and fabricate a trim coping for the dentist to follow. The laboratory can then fabricate the bridge. When the dentist receives the bridge, the dentist only needs to put the trim coping in the patient's mouth, groove the teeth, apply the bonding resin, put the composite into the grooves, press the ladder 10 and truss 20 into the composite, tamp it over, light-cure the ladder 10 and truss 20 into the composite, and finally adjust the occlusion.
The ladder 10 and truss 20 can be used in a variety of different applications. In one exemplary application, the ladder 10 and truss 20 can be used to stabilize mobile teeth up to and including an entire arch using just the ladder 10, or the ladder 10 in combination with the truss 20 or the truss 20 with the substructure 26 for anchoring the pontic. This is accomplished by embedding the ladder 10 and truss 20 into MO, DO, or MOD preparations in the teeth to be stabilized, in which unpolymerized composite resin has been placed. After seating the ladder 10 and truss 20, the resin oozes through the apertures or perforations 16 in the ladder 10 and the apertures 26 in the truss 20. After the resin is sufficiently set, it is tamped down and molded. The composite resin is then light cured or polymerized to create a permanent reinforced bridge.
As shown in
In another exemplary application, the interlocking ladder 10 and truss 20 with substructure(s) 28 and pontic(s) can be used to replace a missing tooth or teeth at any location over the arch. An artificial tooth or teeth can be formed around the substructure 28 by the dentist chair-side either free-hand or with celluloid pontic halves made from composite resin (light-cured or light-polymerized). The artificial tooth or teeth can also be fabricated in a dental laboratory by a dental laboratory technician. The resulting bridge is then bonded in two or more teeth after preparation of those teeth by the dentist and inserting the ladder 10 and truss 20 as previously discussed.
In yet another exemplary application, the interlocking ladder 10 and truss 20 with or without substructure(s) or pontic(s) may be used by a dentist or laboratory technician to construct a reinforced temporary bridge with occlusal stops, eliminating the conventional use of custom castings. The ladder 10 and truss 20 with or without substructure(s) 28 or pontic(s) are incorporated chair-side by the dentist using acrylic or composite resin in conjunction with a vacuum-formed clear celluloid bridge form, or by the laboratory using heat processed acrylic.
In another exemplary application, the ladder 10 and truss 20 as designed without the substructure(s) 28 or pontic(s) can also be formed as one piece, for example, by casting or another method. The formed piece can be made from an appropriate material, such as, for example, titanium, dental hard-gold alloy, crown and bridge non-precious metal, stainless steel, cast ceramic such as Empress, among other materials. The formed piece can fit within an MO, DO, or MOD restoration to act as a reinforcement, contact point or former, occlusal and marginal ridge stops for the MO, DO, or MOD light-cured composite restoration into which they are embedded to enhance the strength, longevity and durability of a light-cured or light-polymerized resin restoration. The formed piece can also be used to reinforce a single temporary crown as previously discussed. The ladder 10 and truss 20 can provide a long lasting temporary crown, which is substantially resistant to occlusal wear.
In yet another exemplary application, the ladder 10 and truss 20, with or without substructure(s) or pontic(s), may also be used by a laboratory to fabricate an all-composite (such as BELLE GLASS) permanent bridges. After the dentist supplies an impression of conventionally prepared teeth, the laboratory can incorporate the ladder 10 and truss 20 with pontic(s) into a composite bridge to reinforce spans of missing teeth. Such structure can substantially resist torquing and provide occlusal stops and mesial and distal marginal ridge stops. Additionally, all of the previously-discussed applications may all be accomplished at the same time in the same arch.
A reinforcing structure 34A extends along an axis 178 (shown in
The reinforcing structure 34A is similar to the reinforcing structure 34 shown in
As shown in
The reinforcing structure 34A defines (see
In the illustrated construction (see
In other constructions (not shown), the structural portion 20A may have a roughened surface in addition to or instead of the apertures 182. The roughened surface may provide improved bonding between the structural portion 20A and bonding resin and/or material of the pontic. The structural portion 20A may define one or more recesses formed in the surface(s) of but not completely through the structural portion 20A in addition to or instead of the apertures 182.
As shown in
As shown in
In other constructions (not shown), the substructure 28A and/or the cross truss 32A may have a roughened surface in addition to or instead of the slots 30A (and/or the apertures 184). The roughened surface may provide improved bonding between the substructure 28A and/or the cross truss 32A and bonding resin and/or material of the pontic. The substructure 28A and/or the cross truss 32A may define one or more recesses formed in the surface(s) of but not completely through the substructure 28A and/or the cross truss 32A in addition to or instead of the slots 30A (and/or the apertures 184).
In some constructions and for some independent features, the dental device may include an insert. The insert may be similar to that described above and shown in
A reinforcing structure, or bridge framework, 34B extends along an axis 178B (shown in
The reinforcing structure 34B is similar to the reinforcing structure 34A shown in
As shown in
The reinforcing structure 34B defines (see
In the illustrated construction (see
In other constructions (not shown), the structural portion 20B may have a roughened surface in addition to or instead of the apertures 182B. The roughened surface may provide improved bonding between the structural portion 20B and bonding resin and/or material of the pontic. The structural portion 20B may define one or more recesses formed in the surface(s) of but not completely through the structural portion 20B in addition to or instead of the apertures 182B.
As shown in
In other constructions (not shown), the substructure 28B and/or the cross truss 32B may have a roughened surface in addition to or instead of the slots 30B (and/or the apertures 184B). The roughened surface may provide improved bonding between the substructure 28B and/or the cross truss 32B and bonding resin and/or material of the pontic. The substructure 28B and/or the cross truss 32B may define one or more recesses formed in the surface(s) of but not completely through the substructure 28B and/or the cross truss 32B in addition to or instead of the slots 30B (and/or the apertures 184B).
A reinforcing structure, or bridge framework, 190 generally includes (see
In the illustrated construction, the reinforcing structure 190 is constructed as a single piece. The reinforcing structure 190 includes a labial side 196 and a lingual side 198. The structural portion 20C sits squarely in easy-to-prepare grooves on the lingual side of adjacent teeth. A pontic, preferably an incisor, is formed around the substructure 28C and is disposed substantially towards the labial side 196.
The reinforcing structure 190 defines (see
In the illustrated construction (see
As shown in
In other constructions (not shown), the structural portion 20C and/or the substructure 28C may have a roughened surface in addition to or instead of the apertures 200 and/or the apertures 184C. The roughened surface may provide improved bonding between the structural portion 20C and/or the substructure 28C and bonding resin and/or material of the pontic. The structural portion 20C and/or the substructure 28C may define one or more recesses formed in the surface(s) of but not completely through the structural portion 20C and/or the substructure 28C in addition to or instead of the apertures 200 and/or the apertures 184C.
The insert 172D includes multiple apertures 126D to, for example, allow resin to flow through and around the insert 172D in creating the composite restoration.
In another construction, the insert 172D may have a roughened surface in addition to or instead of the apertures 126D. The roughened surface may provide improved bonding between the insert 172D and bonding resin and/or material of the pontic. The insert 172D may define one or more recesses formed in the surface(s) of but not completely through the insert 172D in addition to or instead of the apertures 126D.
In another construction, the insert 172E may have a roughened surface in addition to or instead of the apertures 126E. The roughened surface may provide improved bonding between the insert 172E and bonding resin and/or material of the pontic. The insert 172E may define one or more recesses formed in the surface(s) of but not completely through the insert 172E in addition to or instead of the apertures 126E.
As shown in
The framework 34F extends along (see
In the illustrated construction, the projections 24F extend above the upper surface of the structural portion 20F in the occlusal direction, when the dental device is supported, to act as occlusal stops for the pontic 64F (see
In the illustrated construction, slots 204 are formed in each end of the structural portion 20F. Each slot 204 has opposite side walls 206, 208 depending from the upper surface. On opposite sides of the substructure 28F, the structural portion 20F is provided by the side walls 206, 208 connected by the projections 24F.
In the illustrated construction, formation of the projections 24F and the slots 204 causes the apertures 182F to be formed. More specifically, the projections 24F are formed by removing material between adjacent projections 24F. The material is removed to provide a recess having a given depth (to a surface below the occlusal surface of the projections 24F) and length. The slots 204 are formed into the second surface of the structural portion 20F to at least the depth of the recesses such that an aperture 182F is formed in each recess. In other constructions, the apertures 182F may be formed in a different manner such as by forming the slots 204F before or concurrently with removing the material between the projections 24F or by milling.
In the illustrated construction, the recesses are formed with a length that is greater than the width of the structural portion 20F which, after formation of the slots 204 results in elongated apertures 182F. Also, the slots 204 are formed beyond the depth of the recesses such that each aperture 182F is short in the vertical direction. The elongated shape and short height of the apertures 182F may improve flow of bonding resin through the apertures 182F.
The framework 34F defines (see
In the illustrated construction, the pontic 64F is generally formed in an over-sized tooth shape, and material is removed, as necessary, to fit the missing tooth space or endentulous space. The pontic 64F is formed generally symmetrical so that the bridge 35F may be used in any portion of the patient's mouth (top, bottom, left side, right side) and in either orientation of the framework 34F (longer end facing forward or to the rear). The symmetrical pontic 64F is trimmed and shaped to provide the desired replacement tooth. In other constructions (not shown), the pontic 64F may be formed so that the bridge 35F is used in only a given area of the mouth and/or in one orientation of the framework 34F.
The sides of the illustrated pontic 64F are formed contiguous with the transition between the radius surfaces 180F where the substructure 28F joins the structural portion 20F so that when pontic material is removed to provide a proper fit between the abutment teeth during installation, the radius surface 180F may be more exposed (and other portions of the substructure 20F may be exposed) to engage into the preps in the sides of the abutment teeth.
To install the above-described dental devices and dental bridges, a dentist determines how many abutment teeth will be utilized to support the dental device. In some cases, improved support and tooth stability may be achieved by utilizing two abutment teeth on one side of the edentulous space. The teeth and edentulous space are measured to determine the length to be bridged. The teeth are marked indicating the prep length and width. In the illustrated constructions, the maximum length will, for example, accommodate 25 mm for the bicuspid bridge and 35.8 mm for the molar bridge. The dental device can be used as the template to facilitate this marking.
Preparations are cut in the abutment teeth as marked using appropriate MO, DO or MOD preps in the two or three abutment teeth. In the illustrated constructions, the preps may be, for example, slightly more than 1.9 mm wide for a molar bridge and slightly more than 1.7 mm wide for a bicuspid bridge. The preps may have rounded corners to enhance mechanical bonding. Prep depth may be such that the occlusal surface of the occlusal stops of the dental device is contiguous with the surface of the central fossa of the abutment teeth.
The length of the framework is trimmed to fit the preps. The size of the pontic is adjusted to fit the edentulous space. The framework and pontic can be trimmed and shaped with standard dental burs, discs, wheels, etc. When adjusting the size of the pontic, the material of the framework and the radius curve at the pontic-framework junction on both sides of the pontic is maintained. The preps in the adjacent abutment teeth may be adjusted by extending them along the distal and/or mesial side of the abutment teeth to accommodate the radius curve of the framework which, when bonded, may provide improved torsional stability for the dental device.
The gum side of the pontic may be adjusted to fit the tissue of the edentulous space lightly. The pontic may also be fit and adjusted as a sanitary pontic. The gum side of the pontic is finished and polished into an appropriate modified ridge lap or bullet shape. If there is not enough material or if too much material has been removed from the pontic for the desired fit, material can be easily added. The surface of the pontic is roughened, and a thin coat of bonding resin followed by the desired amount of composite resin is applied, cured and shaped. When utilizing the (indirect method), the steps should be done on the model first.
Prior to bonding, the dental device should seat passively into the preps, and the occlusal surface of the occlusal stops should be at least even or slightly above the surface of the central fossa on each abutment tooth. If there is an MOD prep next to an unprepared tooth, an ultra thin matrix band may be placed to establish a non-bonded contact of the composite with the unprepared tooth. Where teeth are to be joined together, wooden wedges may be placed between the teeth to establish the gingival embrasure. Resin will not bond to the wooden wedges. When bonding the dental device into the preps, the directions for the composite resin system being used are followed.
The preps are filed with the composite resin. The framework is pressed into the composite resin so that the resin flows both around the framework and into and through the occlusal perforations. When the dental device is seated into what has been determined to be the desired position, the still uncured occlusal and interproximal composite resin is formed and adapted with instruments moistened with uncured bonding resin. When the position of the dental device and the shape and form of the composite resin are as desired, it is light cured occlusally, buccally and lingually.
The occlusal surfaces, both the composite and the occlusal stops, are adjusted as required for normal bite. The buccal and lingual surfaces are trimmed and adjusted. The embrasures are opened to allow a Proxabrush or Super-Floss to be inserted for easy cleaning. All surfaces of the pontic, truss and cured composite resin are polished, and installation is complete.
One or more independent features or independent advantages of the invention may be set forth in the following claims:
The present application is a continuation-in-part of pending U.S. patent application Ser. No. 12/164,970, filed Jun. 30, 2008, published as U.S. Patent Application Publication No. US 2008-0318186 A1, on Dec. 25, 2008, which is a continuation-in-part of pending U.S. patent application Ser. No. 10/582,038, filed Apr. 11, 2007, published as U.S. Patent Application Publication No. US 2007-0281282 A1, on Dec. 6, 2007, now abandoned, which is the national application of International Application No. PCT/US2004/041981, filed Dec. 15, 2004, published as PCT Patent Application Publication No. WO 2005/058179 A1, on Jun. 30, 2005, which claims priority to prior-filed provisional patent U.S. Application Ser. No. 60/529,475, filed Dec. 15, 2003, the entire contents of all of which are considered as being part of the present application and are hereby incorporated by reference.
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