Dentistry – Method or material for testing – treating – restoring – or...
Reexamination Certificate
1999-09-20
2001-07-03
Lewis, Ralph A. (Department: 3732)
Dentistry
Method or material for testing, treating, restoring, or...
C600S589000, C606S041000, C607S101000
Reexamination Certificate
active
06254389
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates generally to the field of dentistry. More specifically, the present invention relates to a hand-held microwave system for intra-oral dentistry that utilizes microwave energy to cure polymer materials intra-orally so as to produce dental composites having improved physical characteristics, and also utilizes microwave energy to detect the presence of and to preferentially heat caries or cavities, thereby disinfecting and therapeutically treating the caries in a potentially non-invasive manner.
BACKGROUND OF THE INVENTION
The use of polymer materials in the dental arts for the restoration of lost or damaged teeth is well known. Such uses fall into two general categories: (i) the use of polymer materials to produce dental prosthetics, such as dentures, bridges and crowns, that are either permanent or removable articles, and (ii) the use of polymer materials to create dental composites for fillings to repair teeth instead of using conventional amalgam fillings or as veneers to refinish tooth enamel surfaces. The first category of dental articles, dental prosthetics, are created outside of the patient (i.e., extra-oral), typically by making an impression of what the desired article should look like and then molding the article to match the impression. The second category of dental articles, dental composites, are created directly in the patient's mouth (i.e., intra-oral) as fillings or veneers to repair or resurface teeth.
The use of microwave energy in the form of a commercial microwave oven used to process dental prosthetics extra-orally is well known. Various types of flasks and molding equipment that can be used in conjunction with a commercial microwave oven for processing and curing dental articles made of polymers have been developed as described, for example, in U.S. Pat. Nos. 4,971,735, 5,151,279, 5,324,186 and 5,510,411, European Patent No. 0 687 451 A2 and Japanese Patent No. JP7031632A. Examples of polymer resin matrices that are specifically formulated to utilize microwave energy supplied by a commercial microwave oven for the thermal polymerization of the polymers into dental articles are shown in U.S. Pat. Nos. 4,873,269, and 5,218,070 and Canadian Patent No. 2,148,436. The impact of the role played by the polymer initiator in a microwave cured resin matrix has been evaluated by Urabe H. et al. in “Influence of polymerization initiator for base monomer on microwave curing of composite resin inlays,”
Journal of Oral Rehabilitation
, Vol. 26, pp. 442-46 (1999). The repair of dentures and related articles using microwave processing is also described in Turck MD et al, “Microwave processing for dentures, relines, repairs and rebases,”
The Journal of Prosthetic Dentistry
, Vol. 69, No. 3, pp. 340-43 (1993). Generally, dentures cured by commercial microwave ovens have improved mechanical properties, and often have better adaptation than those cured by conventional water-bath method. The primary advantage of microwave curing, however, is the reduced processing times which can be shortened from 8 hours or more to as little as a few minutes.
There had been relatively little research, however, into the potential impact of the microwave energy itself on the polymerization process for dental prosthetics. The research that has been done has generally focused on the duty cycle used for the microwave oven curing process. The impact on porosity of denture material cured using lower wattage, longer duration microwave cure times (i.e., a lower duty cycle for a longer time) versus higher wattage, shorter duration microwave cure times (i.e., a higher duty cycle for a shorter time) is compared in Alkhatib MB, et al. “Comparison of microwave-polymerized denture base resins,”
The International Journal of Prothodontics
, Vol. 3, No. 2, pp. 249-55 (1990). European Patent No. 0 193 514 BI describes a microwave processing system for dental prosthetics that has a magnetron, a waveguide, a surface radiating antenna, a flask, and a temperature sensor that is inserted in the flask and connected to a regulating processor. The regulating processor limits the temperature in the flask as measured by the temperature sensor by turning on and off the magnetron based on frequency modulation of the duty cycle. Although not used for polymerization of dental articles, U.S. Pat. No. 5,645,748 does describe a microwave system for sterilization that controls duty cycle of a microwave oven for the purpose of minimize arcing caused by metallic surgical or dental instruments.
With respect to the second category of dental articles created using polymer materials, dental composites formed of polymer matrix-composites are increasingly being used as an alternative to mercury-containing dental amalgam for aesthetic and restorative dental materials. These kinds of polymer matrix-composites are usually photo polymerizable in that they are cured using some kind of light instead of heat. Generally, the polymer matrix-composite is based on a photo polymerizable polyfunctional methacrylate compound that can be used alone or as mixture with monomethacrylates, light sensitive cure initiators pigments and fillers in a mixture with various comonomers such as triethyleneglycol dimethacrylate. Although the half-life of these polymer matrix-composites cured by light is on the order of 5-8 years and therefore they tend to wear out earlier than conventional dental amalgams, the enhanced biofunctionalilty and more pleasing aesthetic qualities of these polymer matrix-composites have gained favor over conventional dental amalgams.
The main deficiencies of polymer composite resins used as dental composites are surface degradation which leads to inadequate wear resistance, polymerization shrinkage and a lack of density. In addition to the problems previously described for dental prosthetics, micro-shrinkage of polymer dental composites produces interfacial gaps on the surface of the composites, which can results in microleakage through the dental composite. The long-term consequence of such microleakage can be bacterial penetration into the tooth that can cause a variety of adverse reactions in the tooth such as pulp damage, tooth sensitivity, possible pulpal death and loss of adhesion of the dental composite.
Improving the degree of polymerization of polymer matrix-composites is generally considered to be one way of improving their physical and biofunctionality characteristics of polymer dental composites as this would lead to stronger dental composites that are less susceptible to degradation, wear and fracture. It would also lead to improved biocompatibility, since there would be reduced amounts of uncured monomer that could act as a biohazard.
Unlike polymer dental prosthetics, however, the curing of polymer matrix-composites by application of thermal energy generally has not been used to date. Obviously, in the case of the conventional thermal water-bath process, it would be impractical to require a patient to remain at the dentist's office for up to 8 hours with their mouth open and with a tooth immersed in a hot water bath in order to set a thermally polymerizable matrix-composite. It is also not possible to place a patient's mouth into a commercial microwave oven to set a thermally polymerizable matrix-composite.
While there are numerous hand-held medical catheter devices that utilize radio frequency and microwave energy to perform ablations and similar heating operations, for example, in the vascular system of a patient, there have been relatively few uses of thermal or electrical energy applied to hand-held dental tools for intra-oral applications. There have been a few hand-held dental probes that utilize an electrically resistive heated tip for diagnosis of dental decay or for melting a sealing material in an intra-oral context as described, for example, in U.S. Pat. Nos. 4,527,560 and 5,893,713. U.S. Pat. No. 5,421,727 describes the use of radio frequency/microwave energy as part of a hand-held endodontic root canal device to raise the temperature of the i
Lewis Ralph A.
Petersen Brad
LandOfFree
Hand-held microwave intra-oral dental system does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Hand-held microwave intra-oral dental system, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Hand-held microwave intra-oral dental system will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-2503270