Endodontic or root canal therapy is a common procedure in which a dentist or endodontist removes the nerve and dental pulp from a tooth in cases where the nerve has been damaged by a cavity, trauma (e.g., fracture of the tooth), disease (e.g., infection), or other reasons. This procedure not only allows the individual to keep a tooth that otherwise could have had to be removed, but relieves the individual of pain and discomfort.
The treatment typically requires the removal of the pulp tissue from the canal(s). The pulp chamber and root canal(s) of the tooth are then cleaned. Finally, the pulp chamber is shaped and sealed.
The tooth to be treated is either living, and its canals contain a vasculo-nervous bundle, or is dead and its canals then contain a necrotic magma. The pulp canals present the most difficult portion of the tooth to be cleaned. A tooth can be mono- or pluri-rooted, increasing the complexity of the tooth treatment.
Conventional techniques for treating the pulp canals consists of using hand held rods fitted with metal bristles, in the form of rasps or files in a variety of gauges. These techniques require manually removing the vasculo-nervous bundle or the necrotic magma.
These conventional manual techniques present numerous disadvantages. Inherent with the positioning of teeth inside a patients mouth, space is limited to perform this intricate work. In addition, the pulp canals can be extremely fine and can also be of an irregular form. This requires the instruments to be small and delicate, presenting the problem of the instruments breaking within the pulp canal, which may necessitate complete removal of the tooth. In some cases the pulp canal is so fine that mechanical treatment is precluded.
To overcome the problems inherent in mechanical procedures, a variety of biochemical treatments have been employed to chemically attack and decompose the nervous bundle or necrotic magma. For example, ethylene diamine tetracetic acid (EDTA) is commonly employed as a treatment solution that is introduced into the pulp chamber and pulp canals to chemically treat dental roots.
It is important to the successful outcome of the procedure that the pulp chamber and pulp canals be sufficiently cleaned after the vasculo-nervous bundle or the necrotic magma has been removed. The cleaning reduces bacteria and other debris that could result in infection or abscess or otherwise result in a less than satisfactory outcome. The pulp chamber and pulp canals are cleaned with an irrigation solution, e.g., a NaOCl solution or antiseptic solution, to prepare the tooth for sealing.
A variety of techniques are employed to introduce treatment and irrigation solutions into the dental root. The instrumented tooth opening may be flushed using a hand held irrigation device. Manual treatment and irrigation of the dental root is a tedious and time-consuming task. In addition, manual methods may not consistently fill and drain the entire pulp chamber and pulp canals, resulting in less than satisfactory preparation of the tooth.
Mechanical, automated systems for introducing treatment and irrigation solutions into the dental pulp chamber and pulp canals are known. One common system employs a tooth manifold for placement on an instrumented tooth. Such systems are described in U.S. Pat. Nos. 4,021,921 and 4,993,947. The manifold has an inlet chamber for delivery of a solution and an evacuation chamber for draining of the solution. The solution is delivered via the inlet chamber into the pulp chamber, from which it flows into the pulp canals. The pulp chamber and pulp canals define a fluid reservoir. One inherent problem with such systems is delivering the solution to the bottom of the fluid reservoir with sufficient pressure to consistently dislodge debris deep within the pulp canal.
U.S. Pat. No. 6,971,878 provided an improved endodontic irrigator over the prior art and is incorporated herein by reference. The '878 system provided a treatment system that is easy and convenient to use by the dental practitioner. The '878 system is time-efficient and minimizes patient discomfort. However, it may be possible to improve on this system, preferably in the quality of the fluids used within the system. Recent research has indicated that it may be possible to improve the efficacy of fluids by subjecting the fluids to different mediums, such as incorporating light, heat, electricity, and/or ultrasonic energy or vibrations into the system.
While systems have been developed that attempt to incorporate the above qualities within the individual systems, there is still room for improvements within the art, such as introducing the qualities into a closed system. A closed system will operate more efficiently than an open system by preventing the leakage or seepage of wetting agents and solutions, and prevent excess amount of solution to be ingested by a patient. However, known prior art methods and systems that attempt to incorporate light or electricity into the root canal process or other dental processes are open systems. Consequently, the efficacy and effectiveness of the fluids is not improved upon as greatly as possible with the existing systems.
According to one aspect of the invention, a tooth root canal treatment system comprises a manifold having a base member sized and configured to rest on a crown of a tooth and a top member sized and configured to couple with the base member. The base and top members together define an inlet chamber and an outlet chamber. A fluid supply source is coupled to the inlet chamber. A draining mechanism is coupled to the outlet chamber. Means are provided for preventing fluid communication between the inlet chamber and the outlet chamber.
The distal end of a needle is sized and configured for passage through an opening between the inlet and outlet chambers to extend distally beyond the base member. The distal end of the needle is in fluid communication with the outlet chamber. The proximal end of the needle includes an opening in fluid communication with the inlet chamber.
In one embodiment, the needle includes a flexible shaft. In one embodiment, the opening between the top and base members is a perforation. In an alternative embodiment, the opening between the top and base members is a valve, e.g., a duck bill valve.
The fluid delivered may be a treatment solution, e.g., an aqueous sodium hypochlorite solution. The fluid may also be an irrigation solution, e.g., water, or other solutions, such as disinfecting, debriding, chelating, or medicinal solutions.
According to another aspect of the invention, a method of treating a tooth root canal provides a needle having a proximal end and a distal end. The dental practitioner places a base on a crown of an instrumented tooth. The distal end of the needle is passed through an opening in the base and into a pulp chamber and a pulp canal of the tooth. A cap is placed on the base to form a tooth manifold having an inlet chamber and an outlet chamber. The proximal end of the needle communicates with the inlet chamber and the distal end of the needle communicates with the outlet chamber. The inlet chamber is coupled to a fluid source and the outlet chamber is coupled to a draining mechanism. Fluid is drawn through the inlet chamber into the pulp chamber and pulp canal. Spent fluid is evacuated from the pulp chamber and the pulp canal through the outlet chamber.
Another aspect of the invention provides an automated system for treating a tooth root canal having a pulp chamber and pulp canal defining a fluid reservoir. The system comprises a tooth manifold having an inlet chamber and an outlet chamber. The inlet chamber is coupleable to a fluid supply source and the outlet chamber is coupleable to an evacuation source. Means are provided for directing fluid from the inlet chamber to the bottom of the fluid reservoir and for evacuating the fluid through the evacuation chamber from the fluid reservoir.
The system may further include means for increasing the efficiency and efficacy of the systems overall and also for the solution within the system. Such means include using electricity, heat, vibrations and/or light or gas in the system to stimulate the system overall or the efficacy of the solution in the system, which increases the overall efficacy of the system.
Although the disclosure hereof is detailed and exact to enable those skilled in the art to practice the invention, the physical embodiments herein disclosed merely exemplify the invention that may be embodied in other specific structure. While the preferred embodiment has been described, the details may be changed without departing from the invention, which is defined by the claims.
While
The system 10 could also include a gas or gas source to help improve the efficacy of the system. One example of such a gas would be plasma gas. The use of gasses in the prior art was limited, as many of these gasses, such as plasma gas, were found to have deleterious effects on the patients as the gasses traveled passed into the patient's oral and sinus cavities. However, because the present system is a closed system, gasses may be used efficiently with minimal side effects. Thus, as an alternate arrangement the light source 11 of
The system 10 provides for automated cyclic filling of the pulp chamber and pulp canals with a solution and evacuation of the solution from the pulp chamber and pulp canals. The system 10 can be used throughout the multiple phases of the endodontic treatment process. For example, the system 10 can be used to first prepare the tooth by delivering a treatment solution, and subsequently to irrigate the tooth by delivering an irrigation solution.
Further, the system 10 allows the dental practitioner to treat more than one tooth simultaneously. The practitioner simply employs a separate manifold for each instrumented tooth.
The practitioner is able to control the treatment process externally to the mouth of the patient. Once in place, the system 10 requires no or minimal hands-on time, freeing the practitioner, at least temporarily, for other tasks. The automated nature of the system 10 provides generally consistent delivery and evacuation cycles, thereby assuring sufficient filling and evacuation of the fluid reservoir in each cycle and in a time-efficient manner.
With reference now to
The overall configuration of the base 14 allows for placement of the base 14 over a single tooth 26 with the ability to seal the tooth 26 and prevent associated solution (S) from escaping into the patient's mouth. The open bottom configuration also provides communication between the fluid reservoir (i.e., the pulp chamber 32 and pulp canals 34) and the manifold.
The base 14 can be made of any suitable biocompatible material, e.g., silicon.
The base 14 includes an interior recess 36 for receiving a perforated screen 38. The screen 38 includes a plurality of openings 40 and is sized and configured to rest on the recess 36 within the base 14. An annular ridge 42 extends from a lip 44 around the circumferential margin of the base 14 above the screen 38 to mate with the cap 16 (see also
As illustrated in
As
As best illustrated in
In the embodiment illustrated in
The distal end 54 of the needle 18 is passed through a selected opening 40 in the screen 38 and through the bottom 30 of the base 14 into a pulp canal 34 that has previously been instrumented. The length of the needle shaft 48 can be selected to place the distal end 54 of the needle 18 at a desired depth. Desirably, the needle 18 length is selected so that the distal end 54 of the needle 18 extends deep within the pulp canal 34.
A conventional long needle gauge having incremented markings may be provided to the practitioner to measure the depth of the root canal 34 and cut or trim the needle 18 to the desired length (not shown).
The practitioner can chose from the plurality of openings 40 to place the needle shaft 48 at or near the center of the selected pulp canal 34 so as to easily position the distal end 54 of the needle 18 deep within the pulp canal 34. The screen 38 therefore allows the system 10 to accommodate individual anatomy and tooth 26 structure.
The head portion 50 is sized and configured to rest on the screen 38 and to prevent passage of the head 50 through the opening 40. Additional needles 18 may be inserted as needed into other instrumented pulp canals 34 within the tooth 26.
Still referring to
The operating parameters for an electrical device used in connection with the present invention can vary depending on the type of treatment system to be used in connection within the system. For instance, if the electrical device would be used to promote iontophoresis, the electric field range would be approximately 1-500,000 V/m, with a preferred field of around 1000 v/m. The current range would preferably be around approximately 100 μA-100 mA, with a preferable current being variable between about 1-50 mA. Direct or alternating current could be used in the system, with direct current being preferred.
If the electrical device was being used for promotion of electroporation, the preferred frequency would be delivered in a range of 10-50,000 Hz, with a more preferred frequency being around 40 Hz. The preferred potential of the system would be between about 100 V-5000 V, with a current of around 5 mA. However, it is understood that any operating parameters that would be used to improve the system would fall within the scope of the present invention.
As illustrated in
The composition 58 may be delivered in any suitable manner. In the illustrated embodiment, the composition 58 is delivered by a dropper 60 or other suitable pipetting device. Alternatively, the composition 58 may be delivered by brushing the material over the screen 38 with a brush (not shown), or the material may be delivered with the tip of a needle, such as a 20-gauge needle.
The composition 58 is selected so as to provide a satisfactory seal with minimal setting time. The composition 58 may be a resin or a light curable material.
The cap 16 is ladle-shaped or otherwise sized and configured to fit over the base member 14 and couple with the annular ridge 42 of the base 14 in a snug-fit engagement. The cap 16 may be semi-flexible to apply additional pressure on the base skirt 28 around the tooth 26 to further seal the tooth 26.
As shown in
The cap 16 includes an inner surface 62 that, together with the screen 38, defines an inlet chamber 64. Setting or gelling of the sealing composition 58 plugs the openings 40 in the screen 38 to form a barrier defining discrete inlet and outlet chambers 64 and 46 and preventing fluid communication between the chambers 64 and 46. The cap 16 may also include the light source 11 and may be further arranged to receive the lead wire 27, which is designed to make contact with the needle 18.
The cap 16 can be made of any suitable biocompatible material.
The distal end 54 of the needle lumen 52 is in fluid communication with the outlet chamber 46. The inlet chamber 64 is in fluid communication with each needle lumen 52 through aperture 56 in the needle head 50, as previously noted.
The manifold 12 is desirably formed of disposable materials and adapted for single use. The needles 18 may be formed of materials which may be sterilized, e.g., by ethylene oxide, for reuse.
Referring now to
The lead wire 27 is connected to the needle 18, shown as extending through the side of the base 14. As is shown in
The outlet chamber 46 is coupled to the evacuation tubing 22 at an outlet port 72 in the base 14. The evacuation tubing 22 is coupled to a vacuum source as is known in the art (not shown). An evacuation flow control valve 74 may be coupled to the evacuation tubing 22 to permit regulation of the flow of spent solution (S) from the outlet chamber 46.
As represented by arrows in
The vacuum pressure created by the vacuum source draws the spent solution (S) out of the pulp canals 34 and pulp chamber 32 through the evacuation chamber 46 and the spent solution (S) exits the manifold 12 through the evacuation tubing 22, as represented by arrows in
It is desirable that the irrigation and evacuation pressures are approximately balanced or that the evacuation pressure is slightly greater than the irrigation pressure to provide a net negative pressure within the manifold 12. The balanced or slight negative pressure serves to help retain the manifold 12 on the tooth 26 and helps prevent caustic chemicals from passing from the root canals 34 into the sinus cavity.
In use, the tooth 26 is instrumented by conventional techniques as is known in the art. The practitioner then places the base 14 on the instrumented tooth 26 to seal the tooth 26 and the screen 38 is placed on the base 14. A desired number of needles 18 are passed through selected openings 40 in the screen 38 and into the instrumented pulp canals 34. The practitioner then applies sealing composition 58 to the screen 38 and allows the composition 58 to set, thereby creating a floor or barrier between the inlet and outlet chambers 64 and 46.
The cap 16 is coupled to the base 14 to close the manifold 12. The base 14 (and thus evacuation chamber 46) is coupled to the evacuation tubing 22 and vacuum source. The cap 16 (and thus inlet chamber 64) is coupled to the inlet tubing 66 and a treatment solution supply source 20.
The practitioner then programs the system 10 for the desired parameters, selecting cycle time, number of cycles, and volume of solution (S) to be delivered. In preparing multiple teeth 26, each manifold 12 may be programmed separately. The cycles can be discrete or continuous cycles. Likewise, the practitioner will set the parameters for the light, heat, electricity, and/or vibration frequency that will be delivered to the system 10 to increase the efficacy of the system 10.
The system 10 is activated to cycle the treatment solution (S) through the pulp chamber 32 and pulp canals 34. Upon completion of the treatment program, the treatment solution supply source 20 is disconnected and the inlet tubing 66 is coupled to an irrigation solution supply source 20.
The system 10 is again programmed for the desired cycle parameters and the system 10 activated to cycle the irrigation solution (S) through the pulp chamber 32 and pulp canals 34. Upon completion of the irrigation program, the needles 18 and the manifold 12 are removed. The endodontic procedure may then be completed as necessary, e.g., by introducing filling material into the prepared pulp canals 34 (not shown).
A flexible skirt 82 is adapted to be placed over the crown 24 of an instrumented tooth 26. The skirt 82 has an opening 84 to accommodate the passage of a tooth manifold 86. Together with the manifold 86, the skirt 82 acts to vacuum seal the tooth 26 to prevent leakage of solution (S) into the patient's mouth. In the illustrated embodiment, the skirt 82 extends 360 degrees around the tooth 26. However, the skirt 82 need not extend 360 degrees around the tooth 26 to assure retention of the skirt 82 on the crown 24 and sealing of the tooth 26.
The skirt 82 can be made of any suitable biocompatible material. The skirt 82 is desirably adapted to be disposable after a single use.
The manifold 86 includes a base portion 88 having an open bottom 89 and defining an outlet or evacuation chamber 90. The base 88 passes through the opening 84 in the skirt 82 and is desirably flanged to rest on the crown 24 of an instrumented tooth 26. The evacuation chamber 90 is in fluid communication with the pulp chamber 32 and pulp canals 34. The outlet chamber 90 is coupled to an evacuation tubing 92 at an outlet port 94 in the base 88. The evacuation tubing 92 is coupled to a vacuum source as in known in the art (not shown). An evacuation flow control valve 96 may be coupled to the evacuation tubing 92 to permit regulation of the flow of the solution (S) from the outlet chamber 90.
The manifold 86 includes an upper or cap portion 98 defining an inlet chamber or reservoir 100. A partitioning wall 102 partitions the cap 98 from the base 88 to prevent communication between the inlet and outlet chambers 100 and 90. The inlet chamber 100 is coupled to a low-pressure fluid supply source 104 by an inlet tubing 106 at an inlet port 108 connector on the cap 98. An inlet flow control valve 110 may be coupled to the inlet tubing 106 to permit regulation of the flow of the solution (S) into the inlet chamber 100.
The cap portion 98 includes a plurality of valve apertures 112, e.g., duck bill apertures. In the closed position, the valves 112 prevent communication between the base 88 and the cap 98, i.e., between the outlet and the inlet chambers 90 and 100. In a preferred embodiment, each valve 112 is normally biased in the closed position. In the open position, the valves 112 permit communication between the base 88 and the cap 98, i.e., between the outlet and the inlet chambers 90 and 100.
The manifold 86 can be made of any suitable biocompatible material. The manifold 86 is desirably adapted to be disposable after a single use.
In a preferred embodiment, each valve aperture 112 is adapted to receive a needle 114 for placement of the needle 114 deep within a selected pulp canal 34 (which has been previously instrumented). The needle 114 permits pressured release of solution (S) and evacuation of the spent solution (S) from deep within the pulp canals 34. It is contemplated that the number and placement of the valve apertures 112 may be varied to accommodate a particular tooth 26 structure and individual anatomy.
As best seen in
The head 120 includes an opening or solution input aperture 124 that is in fluid communication with the needle lumen 118. The head 120 can be made of any suitable biocompatible material. The head 120 is sized and configured for placement within a valve aperture 112 to move the valve 112 from the closed to the open position. The needle head 120 is desirably of a complementary geometry to the valve aperture 112 to provide a snug fig engagement within the valve. The snug fit engagement secures the needle 114 within the manifold 86 while maintaining discretion between the inlet and outlet chambers 100 and 90. In the illustrated embodiment, the head 120 is a circular hub permitting rotation of the needle 114 within the valve 112 to enable proper alignment of the needle 114.
Desirably, the head 120 includes a sealing member 126. The sealing member 126 serves to minimize leakage of solution (S) from the needle head 120 and/or the inlet chamber 100. The sealing member 126 may be integral with the head 120 or molded as a separate piece for selective, removable engagement with the head 120.
As represented by arrows in
The vacuum pressure created by the vacuum source draws the spent solution (S) out from pulp canals 34, pulp chamber 32 and evacuation chamber 90 through the evacuation tubing 92, as represented by arrows in FIG. 18.
The foregoing is considered as illustrative only of the principles of the invention. Furthermore, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described. While the preferred embodiment has been described, the details may be changed without departing from the invention, which is defined by the claims.
This application is a continuation of U.S. patent application Ser. No. 11/634,703, filed 6 Dec. 2006.
Number | Date | Country | |
---|---|---|---|
Parent | 11634703 | Dec 2006 | US |
Child | 12590051 | US |