Irrigation and aspiration handpiece

Information

  • Patent Grant
  • 6464498
  • Patent Number
    6,464,498
  • Date Filed
    Tuesday, March 27, 2001
    23 years ago
  • Date Issued
    Tuesday, October 15, 2002
    22 years ago
  • Inventors
  • Examiners
    • Wilson; John J.
    Agents
    • Ryan Kromholz & Manion, S.C.
Abstract
An assembly for aspirating and irrigating an endodontic or other cavity. The assembly includes a handpiece having at least one fluid discharge inlet and a vacuum outlet. The assembly further includes a surgical needle connected to the handpiece by way of a L-shaped connector. The L-shaped connector is arranged to support the needle while concurrently providing communication between a fluid discharge tube and an aspiration tubing.
Description




BACKGROUND OF THE INVENTION




This invention relates to multipurpose dental handpieces, and in particular, handpieces which irrigate and aspirate during endodontic procedures, such as root canal surgery. During endodontic procedures, such as root canals, it is necessary to inject or applicate fluid into the dental pulp or root. Additionally, debris and other matter must be removed from the dental cavity. Presently, typical handpieces used for these types of procedures are designed to spray fluid, under positive pressure, into the tooth cavity. This arrangement has been known to cause a number of difficulties, most notably damage to the tooth cavity caused by undue fluid force.




During a typical root canal procedure, a dental practitioner drills an opening in a patient's tooth surface enamel and inner dentine to gain access to the dental pulp and surrounding cavity. A hollow, surgical needle is inserted into the opening to both remove decaying pulp tissue by aspiration, and irrigate the cavity with sodium hypochlorite solution. The sodium hypochlorite solution rids the canal of bacteria and other foreign substances before sealant is injected into the canal. The dental pulp cavity is curvately elongate and tapers into the root area of the affected tooth. Common dental practice at this time includes the use of a handpiece fitted with a rigid, stainless steel needle whereby the practitioner alternatively aspirates and irrigates the canal. Several problems are encountered with this arrangement. First, since a stainless steel needle is relatively rigid with respect to the tooth canal and cavity, care must be taken not to puncture the tooth wall and surrounding jaw. Further, access to the extreme distal end of the curved root cavity is not possible due to the rigid nature of the needle. Additionally, the force by which fluid is discharged through the needle can create undue pressure on the tooth walls and surrounding tissue, making full aspiration and irrigation of the canal without damage extremely difficult.




SUMMARY OF THE INVENTION




It is therefore an object of this invention to provide an endodontic handpiece assembly capable of irrigating a root canal safely and accurately, while additionally providing aspiration. The handpiece of the invention is provided with means for irrigation and means for aspiration, wherein irrigation is supplied through gravity and surface tension feed. This arrangement lessens the unwanted effects of pressure-applied irrigation while providing the convenience of a dual purpose tool. A control mechanism is disposed on the handpiece, which controls whether fluid dispenses from a fluid discharge nozzle, aspirating vacuum is supplied to a aspiration nozzle, or a combination of irrigation and evacuation is performed.




The assembly further comprises an autoclavable endodontic needle assembly capable of curving to the configuration of a root canal while being inserted therein. The needle of the present assembly may be produced to be pre-bent to a desired angle; the preferred angle chosen is 45 degrees. The needle of the present invention may also be provided with an angle-adjustment sleeve around a portion of the needle to allow for manual adjustment of the pre-bent angle.




It is to be further noted that use of sodium hypochlorite solution as an irritant can be caustic and have an adverse affect on the preferred binary NiTi alloy of the needle. To substantially eliminate the possibility of the solution corroding or deteriorating the NiTi alloy, a coating, such as a parylene polymer, may be applied to the needle during its manufacture. While parylene polymers are the preferred coatings, there are other commercially available coatings that provide similar protection.




It is a further object of the present invention to provide a unique tip for the needle. The tip portion of the present invention includes a skived area at the most distal end of the needle. The skived area allows side venting and prevents vacuum buildup during aspiration of the root canal. The unique tip is further capable of functioning within the narrow and curved confines of a root canal.




The assembly is further provided with an L-shaped connector having two legs. The connector provides communicative connection between both the needle and the aspiration nozzle, and the needle and the discharge nozzle. Each leg of the connector includes a through bore which terminates in an aperture. A third aperture is provided intermediate the ends of the legs. The needle is attached to the handpiece by way of the L-shaped connector and an adhesive-filled supporting hub member which grippingly engages the needle shaft to provide connection to a conventional LUER® lock. The needle is positioned in one leg of the connector and through its bore, such that an attachment end of the needle is simultaneously positioned through the third aperture.




The needle shaft is thereby grippingly received in one bore leg while its attachment end extends through the third aperture where a supporting hub member supports the attachment end to provide connection with a conventional LUER® lock. The LUER® lock is adapted to be received by the aspiration nozzle by way of an interference fit.




The second leg of the L-shaped connector is adapted to receive a flexible tubing length having a through-bore. One end of the tubing is arranged to fit over the second leg aperture while the second end fits over the discharge nozzle. This arrangement allows communication between the discharge nozzle and the second leg of the L-shaped connector. As fluid flows from the discharge nozzle, through the second leg bore it encounters the needle shaft in position in the first leg bore. The fluid then moves out of the first leg aperture along the outside of the needle shaft. The fluid is drawn down the needle shaft and toward the needle tip by surface tension and gravity pull, rather than the positive pressure present in prior art arrangements.











DESCRIPTION OF THE DRAWINGS





FIG. 1

is perspective view of the handpiece and needle of the present invention.





FIG. 2

is a partially cut-away cross sectional view taken along lines


2





2


of FIG.


1


.





FIG. 3

is an enlarged view of the cross sectional area seen in FIG.


2


.





FIG. 4

is a view similar to the view of

FIG. 3

, but showing the general direction of irrigation fluid traveling on the outer surface of the needle shaft and toward the distal end of the needle, and the direction of aspiration into the bore of the needle.





FIG. 5

is an exploded view of the needle assembly and connector of the present invention.











DETAILED DESCRIPTION




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 which 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.




The term “fluid”, as used herein, shall be defined as a gas, a liquid, a substance which flows, or a substance which differs from a solid in that it can offer no permanent resistance to change of shape. It shall further include mixtures of gases, mixtures of liquids, and mixtures of gases and liquids.




With reference to

FIG. 1

, an assembly


10


capable of dispensing fluids to and evacuating a cavity (not shown) during endodontic procedures is seen. The assembly


10


includes a handpiece


12


and a needle assembly


14


. The handpiece


12


includes a distal end


16


and a proximal end


18


, the proximal end


18


being adapted for facile gripping by a dental practitioner. As seen in

FIG. 2

, the distal end


16


includes a fluid discharge nozzle


20


and an aspiration nozzle


22


. A control mechanism, seen as manual switch


24


, is disposed on the handpiece


12


. The control mechanism


24


controls whether fluid dispenses from the fluid discharge nozzle


20


, aspirating vacuum is supplied to the aspiration nozzle


22


, or a combination of irrigation and evacuation is performed. The switch


24


may also be provided with a finger-less lock-on feature that permits the switch to be maintained in an “on” position without the need for constant finger operation by the user. Alternatively, the handpiece may be provided with separate switches


24


for each aspiration or irrigation function. At least one fluid inlet


26


and one fluid outlet


28


, are each disposed, preferably at the proximal end


18


of the handpiece


12


.




The assembly


10


further comprises an autoclavable endodontic needle assembly


14


. As seen particularly in the views of

FIGS. 2-5

, the needle assembly


14


includes a surgical needle


30


having a shaft


31


including a hollow bore


32


, a tip portion


34


and an end attachment portion


36


. The needle


30


is preferably mounted on a hub member or hub apparatus


38


. The hub apparatus


38


is preferably provided with a cup-like interior and is arranged for mating arrangement with a conventional LUER® connector


40


. The connector


40


is also commonly referred to as a slip LUER® or a LUER® lock fitting. The hub apparatus


38


is molded from autoclavable material, such as Ultim 1000, obtainable from General Electric Corporation.




The needle


30


is preferably fabricated from a binary NiTi alloy, whereby the needle


30


is capable of curving to the configuration of a root canal while being inserted therein. The preferred binary NiTi alloy contains 55.8 weight percent Nickel. The needle


30


of the present needle assembly


14


may be produced to be pre-bent to a desired angle; the preferred angle chosen is 45 degrees. The needle


30


of the present invention may also be provided with an angle-adjustment sleeve


58


, best seen in FIG.


5


. The angle adjustment sleeve


58


may be arranged around a portion of the needle


30


shaft


31


to allow for manual adjustment of the pre-bent angle.




It is to be further noted that use of sodium hypochlorite solution as an irrigant can be caustic and have an adverse affect on the preferred binary NiTi alloy of the needle


30


. To substantially eliminate the possibility of the solution corroding or deteriorating the NiTi alloy, a coating (not seen in these views), such as a parylene polymer, may be applied to the needle


30


during its manufacture. While parylene polymers are the preferred coatings, there are other commercially available coatings that provide similar protection. The coating inhibits the sodium hypochlorite solution from adversely affecting the physical properties of the dental needle


30


.




The tip portion


34


of the needle


30


of the present assembly


10


preferably includes a skived area


42


. The skived area


42


allows side venting and prevents vacuum buildup during aspiration of the root canal (not shown). The unique tip


34


is further capable of functioning within the narrow and curved confines of a root canal.




As seen in

FIG. 2

, the handpiece


12


is preferably adapted to contain two fluid passageways


44




a


,


44




b


. The first passageway or fluid draw line


44




a


provides a pathway for fluid moving from a fluid source (not shown) to the discharge nozzle


20


. The second passageway


44




b


provides a pathway for evacuation of fluid and debris from the distal end or tip


34


of the needle


30


to a outlet reservoir or vacuum source (not shown).




As seen more particularly in

FIGS. 3-5

, the assembly


10


is further provided with an L-shaped connector


46


having a first leg


48




a


and a second leg


48




b


. The L-shaped connector


46


includes a through-bore


50


which is arranged to provide passageway through the first leg


48




a


and the second leg


48




b


. Each of the legs


48




a


,


48




b


terminate at a respective distal end


52




a


,


52




b


, each distal end includes a respective-leg aperture


54




a


,


54




b


communicating with the bore


50


. A third aperture


56


is arranged intermediate the ends


52




a


,


52




b


of the legs


48




a


,


48




b


. The third aperture


56


is further arranged for communication with the L-shaped through-bore


50


.




The needle


30


is attached to the handpiece


12


by way of the L-shaped connector


46


and the adhesive-filled supporting hub member


38


which grippingly engages the needle shaft


32


to provide connection to a conventional LUER® lock


40


. The needle


30


is positioned in the first leg aperture


54




a


and through the first leg


48




a


of the through-bore


50


, such that the attachment end


36


of the needle


30


is simultaneously positioned through the third aperture


56


. Additional adhesive


70


may be used to seal the area around the third aperture


56


and needle attachment end


36


. The needle shaft


32


is thereby grippingly received in the first bore leg


48




a


, while the attachment end


36


extends through the third aperture


56


and is supported by the supporting hub member


38


to provide connection with a conventional LUER® lock


40


. The LUER® lock


40


is adapted to be received by the aspiration nozzle


22


(seen in FIG.


2


), thereby completing the connection from aspiration nozzle


22


to needle tip


34


by way of the L-shaped connector.




The second leg


48




b


of the L-shaped connector


46


is adapted to receive a flexible tubing length


60


having a through-bore


62


. As best viewed in

FIGS. 2 and 5

, the flexible tubing length


60


includes two ends


64




a


,


64




b


. The first end


64




a


is arranged to fit over the second leg


48




b


of the connector


46


, while the second end


64




b


fits over the discharge nozzle


20


of handpiece


12


. This arrangement allows communication between the discharge nozzle


20


and the second leg


48




b


of the L-shaped connector


46


. The handpiece may optionally be provided with tubing clips


72


, seen in

FIG. 5

, to aid in positioning the tubing length


60


between the fluid discharge nozzle


20


and the second leg


48




b


of the L-shaped connector


46


.




As illustrated particularly in

FIG. 4

, when fluid discharge is desired, fluid


66


flows from the discharge nozzle


20


, of the handpiece


12


and through the tubing


60


bore


62


. The fluid


66


continues through the second leg


48




b


bore


50


until it encounters the needle shaft


32


in position in the first leg


48




a


bore


50


. The fluid


66


then moves out the first leg aperture


54




a


along the outer surface


68


of the needle shaft


32


. The fluid


66


is drawn down along the outer surface


68


of the needle shaft


32


and toward the needle tip


34


through surface tension and gravity pull, rather than the positive pressure present in prior art arrangements.




During fluid discharge, the outer surface


68


of the needle shaft


32


acts as a conduit to direct the fluid


66


toward a desired irrigation site, such as a dental cavity (not shown). Aspiration of the site is done through the needle bore


32


, as indicated by the arrows in FIG.


4


. The bore


32


of the needle


30


communicates with the LUER® connector


40


which allows the aspirate (not shown) to be carried through the aspiration nozzle


22


and out the fluid outlet


28


(seen in FIG.


1


).




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.



Claims
  • 1. An assembly for dispensing fluids and for evacuating a cavity during an endodontic procedure, the assembly comprising:a handpiece including means for fluid discharge and means for evacuation; at least one inlet and at least one outlet disposed on said handpiece; a control mechanism disposed on said handpiece, the control mechanism controlling discharge and evacuation to and from said handpiece; a surgical needle having a hollow shaft connected to said handpiece; a connector communicating with said means for fluid discharge and said means for evacuation; and said connector further including means for communicating with and supporting a surgical needle, said needle further including an external surface substantially coextensive of its length and a coextensive bore, said bore being arranged to communicate with said means for evacuation; said external surface of said needle being arranged for transport of a selected irrigation fluid, said irrigation fluid being transported along said external surface of said needle by way of needle surface tension and gravity.
  • 2. The assembly of claim 1 wherein said external surface of said needle is arranged to communicate with said connector and said means for discharge.
  • 3. The assembly of claim 1 wherein said connector is L-shaped and includes first and second communicating hollow legs, each of said legs defining a coextensive bore.
  • 4. The assembly of claim 3 wherein said hollow needle is located in one of said coextensive bores, said one of said coextensive bores communicating with said inlet of said handpiece.
US Referenced Citations (62)
Number Name Date Kind
611136 Mason Sep 1898 A
1672114 Crow Jun 1928 A
RE21187 Hooper Aug 1939 E
2214230 Freeburg Sep 1940 A
2557222 Goode Jun 1951 A
2711586 Groves Jun 1955 A
2756740 Deane Jul 1956 A
2812765 Tofflemire Nov 1957 A
2929510 Penn Mar 1960 A
2985285 Riddle May 1961 A
3164153 Zorzi Jan 1965 A
3208145 Turner Sep 1965 A
3593423 Jones et al. Jul 1971 A
3624907 Brass et al. Dec 1971 A
3640304 Fox et al. Feb 1972 A
3645497 Nyboer Feb 1972 A
3727310 Baker Apr 1973 A
3816921 Malmin Jun 1974 A
4021921 Detaille May 1977 A
4106198 Childress Aug 1978 A
4215476 Armstrong Aug 1980 A
4227878 Lohn Oct 1980 A
4253831 Eaton, II Mar 1981 A
4340365 Pisanu Jul 1982 A
4353694 Pelerin Oct 1982 A
4397640 Haug et al. Aug 1983 A
4526573 Lester et al. Jul 1985 A
4552531 Martin Nov 1985 A
4578055 Fischer Mar 1986 A
4752444 Bowen et al. Jun 1988 A
D302586 Zogg et al. Aug 1989 S
4872837 Issalene et al. Oct 1989 A
5044953 Sullivan Sep 1991 A
5052927 Discko, Jr. Oct 1991 A
5057283 Guggenheim et al. Oct 1991 A
5061180 Wiele Oct 1991 A
5087198 Castellini Feb 1992 A
5171146 Guerci Dec 1992 A
5204004 Johnson et al. Apr 1993 A
5230704 Moberg et al. Jul 1993 A
5236356 Davis et al. Aug 1993 A
5289919 Fischer Mar 1994 A
5295825 Grosrey Mar 1994 A
5318443 Overmyer Jun 1994 A
5348711 Johnson et al. Sep 1994 A
5378149 Stropko Jan 1995 A
5378150 Harrel Jan 1995 A
5419772 Teitz et al. May 1995 A
5468148 Ricks Nov 1995 A
5474450 Chronister Dec 1995 A
5526841 Detsch et al. Jun 1996 A
5554026 Van Hale Sep 1996 A
5556279 Wolf et al. Sep 1996 A
5593304 Ram Jan 1997 A
5658144 Tinder et al. Aug 1997 A
5716210 Novak Feb 1998 A
5772433 Esrock Jun 1998 A
5837204 Prevost et al. Nov 1998 A
5853384 Bair Dec 1998 A
5876201 Wilson et al. Mar 1999 A
5899692 Davis et al. May 1999 A
5947990 Smith Sep 1999 A
Non-Patent Literature Citations (1)
Entry
Kent Dental —Spring / Summer 1984 Product Catalog —p. 153-154.