The present invention relates to dentistry and more particularly to a system for releasably locating, supporting and retaining a denture.
Dental implants are used to support one or more artificial teeth. Implants can help support, stabilize and retain full dentures. Suction aids retention of upper full dentures, but suction is generally inadequate for retention of lower full dentures.
At present there are two kinds of dentures, generally termed “hard dentures” and “soft dentures”. Hard dentures are made out of any type of plastic and are unlined. Soft dentures have a rigid structure with a liner made of a soft, cushioning material, such as silicone, in the inner channel over the patient's gingival tissue. Some prior known implants systems for dentures use a ball shaped abutment that projects from each implant. Hard dentures are retained by screws that extend through the denture and into the implants. An alternative system for retaining hard dentures has a cap or holder imbedded in the channel of the denture. The cap has a rubber or elastomeric “O” ring that snaps over a ball shaped abutment on the implant. The implants support the hard dentures with these retention systems and the forces of chewing are on the implants.
The liner in a soft denture is intended to cushion and support the denture on the gingival tissues. One known system for retaining a soft denture has cavities opening into the inner channel. The liner extends into and lines the cavities, and shaped abutments on the implants protrude into the cavities to retain the denture. These systems require complex cavity and abutment shapes in order to provide sufficient retention.
There are two main types of implant systems currently in use. The first type uses what is generally known as a large diameter implant and is greater than 3 mm in diameter. This system is generally a two piece system that includes an implant with an internally threaded cavity and an abutment that threads into the cavity in the implant. The large diameter implant system is very stable after it fuses to the bone, allows precise selection of the abutment height after the implant is installed, and after years of use the abutment neck height can be changed to accommodate receding tissues. However, the large diameter implant is more difficult to place by the General Dentist and is most often placed by a specialist, is more expensive to make and install, has a higher risk of damage to the nerves in the bone, and there is usually a 2 to 3 month wait for the bone to fuse to the implant.
The second type of implant system uses what is generally known as a mini or small diameter implant with the implant diameter being less than about 3 mm. Since the diameter of the implant is substantially too small for a cavity with internal threads, in this system the implant and abutment are generally one piece. The mini implant is easy for the General Dentist to install, is less expensive to make and install, is usually easier to place, has a lower risk of damage to the nerves in the bone, is screwed tightly into the bone without invasive surgery and can be loaded immediately. However, the mini implant is smaller and thus less stable under heavy loads, and can be placed by less trained dentists, resulting in the risk of abuse and misplacement. The one piece mini implant is harder to get the correct length, and can protrude too far into the denture base, such that a soft denture is supported by the implant instead of the gingival tissue.
U.S. Pat. No. 4,787,851 to Kusano, et al. discloses a denture having an inner channel with an elastomeric liner and ball shaped abutments that project into the liner. U.S. Pat. No. 2,112,007 to Adams discloses a denture having an inner channel with snap ring cup sockets and ball shaped abutments that project into the sockets. U.S. Pat. No. 5,049,072 to Lueschen discloses a denture having an inner channel with sockets, o-rings and ball shaped abutments that project into the sockets.
There is a need for a denture retention system that sufficiently retains the denture while allowing the gingival tissue to support the denture. In such a system there is the further need of being able to precisely select the abutment height and to adjust the abutment height to accommodate receding tissues, with both large diameter and mini implants.
A system for retaining a denture on gingival tissue, where the denture has an outer side with a plurality of artificial teeth, an inner side with an inner channel, and a resilient liner in the inner channel, includes at least one abutment, a substantially rigid engaging cap for each abutment, and an implant for each abutment. The abutment has a substantially spherical head, a neck connected to the head and a base connected to the neck. The neck has a diameter smaller than said head. The engaging cap is rigidly mounted in the denture. The engaging cap has an end portion with a first face and a spaced second face, and an enclosing fence formed by a plurality of spaced fingers that project transversely from the second face to define a cavity with an open end. The cavity is sized to receive the head of the abutment. The fingers each have an inwardly projecting lip portion opposite the end portion to retain the head in the cavity. The cavity is sized longitudinally to space the head from the end portion when the lip portions contact the head so that the liner supports the denture on the gingival tissue while the abutment restricts movement of the denture away from the gingival tissue. The head of the abutments has a plurality of spaced, tool engageable flats for tightening the abutment on the implant. Large diameter and mini implants can be used with the system.
Details of this invention are described in connection with the accompanying drawings that bear similar reference numerals in which:
Referring to
As shown in
The head 27 has a plurality of spaced, radially outwardly facing flats 31. The flats 31 can be engaged by a tool, such as a socket, to tighten the abutment 15. The head 27 shown has four flats 31. Preferably the flats 31 are uniformly spaced and the head 27 has at least four flats 31.
A cylindrical abutment aperture 32 with internal threads 33 extends into the abutment 15 from the base 29, opposite the neck 28. A hollow, cylindrical skirt 34 projects from the periphery of the base 29, opposite the neck 28. The end 35 of the skirt 34, opposite the base 29, has an inwardly facing bevel or taper 36.
Referring to
A tool engageable section 46 projects from the first end 39 of the implant 16. The tool engageable section 46 has a plurality of spaced, radially outwardly facing flats 47 that are connected by corners 48. The corners 48 can be flat or rounded. Preferably the flats 47 are uniformly spaced around the tool engageable section 46. The tool engageable section 46 shown has four flats 47. Other numbers of flats 47 can be used.
An externally threaded abutment connecting member 50 projects from the tool engageable section 46, opposite the first end 39 of the implant 16. The abutment connecting member 50 is sized to thread into the abutment aperture 32. When the abutment 15 is threaded onto the implant 16, the corners 48 on the tool engageable section 46 allow the skirt 34 to fit over the tool engageable section 46, and the taper 36 on the skirt 34 seats on the taper 44 at the first end 39 of the implant 16, to provide a tight fit and to secure the abutment 15 on the implant 16. The height of each abutment 15 can then be precisely selected with the two piece system of abutment 15 and implant 16. The structure of the implant 16 with the abutment 15 can be used as a two piece mini implant system, as well as a large diameter implant system.
The fence 54 projects transversely from the second face 57 to define a hollow, cylindrical cavity 61 with an open end 62 opposite the end portion 53. The fence 54 shown includes a plurality of spaced fingers 64 that project transversely from the second face 57 of the end portion 53. The fingers 64 each have a radially inwardly projecting lip portion 65 opposite the end portion 53. As shown in
The cavity 61 is sized longitudinally so that the head 27 is spaced from the end portion 53 when the means 67 for releasably retaining the head 27 in the cavity 61 contacts the head 27. The height of each abutment 15 can then be precisely selected so that the denture 14 is supported on the gingival tissue 25 by the liner 24, instead of being supported by the abutments 15 and implants 16, while the abutments 15 restrict movement of the denture 14 away from the gingival tissue 25. Chewing forces are thereby exerted against the liner instead of through the abutments 15 to the implants 16. The size of the head 27 of the abutment 15 relative to the cavity 61 can be selected to modify the retention force of the denture 14 by the engaging caps 17. A larger head 27 will provide a greater retention force while a smaller head 27 will provide a lower retention force.
The inner channel 23 is shaped to receive the gingival tissue 25. The inner channel 25 has a base and opposed sides extending away from the base and terminate in two ends. The resilient liner 24 extends into inner channel 24 along the sides from the two ends to contact the engaging cap 17 and surrounds each engaging cap across the base of the inner channel.
The head 73 has a plurality of spaced, radially outwardly facing flats 78. The flats 78 can be engaged by a tool, such as a socket, to tighten the abutment 70. The head 73 shown has four flats 78. Preferably the flats 78 are uniformly spaced and the head 73 has at least four flats 78. The implant connecting member 76 has external threads 79 that are spaced from the base 75 and an inward taper 80 from the base 75 to the threads 79.
Referring to
The abutment aperture 87 is sized to receive the implant connecting member 76 on the abutment 70, and the taper 89 of the abutment aperture 87 is complementary to the taper 80 of the implant connecting member 76. When the abutment 70 is threaded onto the implant 71, the taper 80 of the implant connecting member 76 seats on the taper 89 of the abutment aperture 87, to provide a tight fit and to secure the abutment 70 on the implant 71. The height of each abutment 70 can then be precisely selected with the two piece system of abutment 70 and implant 71.
As shown in
Although the present invention has been described with a certain degree of particularity, it is understood that the present disclosure has been made by way of example and that changes in details of structure may be made without departing from the spirit thereof.
Number | Name | Date | Kind |
---|---|---|---|
2112007 | Adams | Mar 1938 | A |
3921293 | Keumurdji | Nov 1975 | A |
4204321 | Scott | May 1980 | A |
4431416 | Niznick | Feb 1984 | A |
4787851 | Kusano | Nov 1988 | A |
5030094 | Nardi et al. | Jul 1991 | A |
5049072 | Lueschen | Sep 1991 | A |
5092770 | Zakula | Mar 1992 | A |
5098295 | Durr et al. | Mar 1992 | A |
5417570 | Zuest et al. | May 1995 | A |
5520540 | Nardi et al. | May 1996 | A |
5556280 | Pelak | Sep 1996 | A |
5662475 | Mena | Sep 1997 | A |
5678997 | De Buck | Oct 1997 | A |
5885077 | Jeffer | Mar 1999 | A |
5997300 | Tseng | Dec 1999 | A |
6302693 | Mena | Oct 2001 | B1 |
6506052 | Hoffman | Jan 2003 | B1 |
6685473 | Weissman | Feb 2004 | B2 |
6981871 | Mullaly et al. | Jan 2006 | B2 |
7234940 | Weissman | Jun 2007 | B2 |
7431589 | Weissman | Oct 2008 | B2 |
7758346 | Letcher | Jul 2010 | B1 |
7785108 | Tache et al. | Aug 2010 | B2 |
7959439 | Bulloch et al. | Jun 2011 | B2 |
7985071 | Weissman | Jul 2011 | B2 |
20050019730 | Gittleman | Jan 2005 | A1 |
20060269903 | Bulard et al. | Nov 2006 | A1 |
20090263761 | Shepard | Oct 2009 | A1 |
20090263762 | Shepard | Oct 2009 | A1 |
20090263763 | Shepard | Oct 2009 | A1 |
Number | Date | Country | |
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20140038133 A1 | Feb 2014 | US |