SE453356B - SCREW PIN FOR INSERTING IN A DENTAL ROUTE - Google Patents

Description

The above-mentioned problems with the screw pins of the prior art are intended to be solved by the present invention. The invention provides a screw pin which is screwable into the tooth root channel by means of a screwdriver, which is set to give a predetermined torque in the screw pin to prevent application of excessive force and load to the walls of the tooth root and to allow the screw pin to be threaded in without crack the tooth. After the screw pin has been inserted into the tooth, it is anchored by means of cement to prevent forces that could otherwise cause the pin to be unscrewed from the seat in the tooth root. These anti-rotation forces are aided by the normal expansion of the threaded legs in the screw pin to higher frictional engagement with the threads in the tooth root canal. They also have the help of the cement which is anchored in irregularities in the tooth wall and in the slit between the bones.

The above description as well as further objects, features and advantages of the invention are described in the following with reference to a suitable, illustrative embodiment according to the invention in connection with the accompanying drawing, in which Fig. 1 shows on a large scale a side view of a screw pin according to Fig. 2 is a perspective view of a shock absorbing element for use with the screw pin in Fig. 1, Fig. 3 is a perspective view of the screw pin in Fig. 1 in combination with a torque wrench according to the invention, Fig. 4 is a large scale shown side view of another embodiment of the screw pin, Fig. 5 is a longitudinal section along the line 5-5 in Fig. 3, Fig. 6 is a perspective view of another screw pin and Fig. 7 partly in section shows a screw pin according to the invention screwed into a tooth root with a crown.

Referring to Figs. 1, 2 and 3, the screw pin in its entirety has the designation 10 and comprises a shaft 12 made in one piece with a body 14 and a crown bracket 16. The shaft 12, the body 14 and the crown bracket 16 are connected and are formed in a paragraph. Although the parts are identified separately, none of them is intended to be normally distinguishable from the others.

The shaft 12 has a length which is greater than the length of the root canal in which the shaft is arranged to be threaded and can therefore be cut to the length of the root canal with a diamond grinding wheel. After the pulp has been removed from the root canal 19 and the canal has been blocked, it is cut off to a diameter corresponding to the shaft 12.

The shaft 12 is divided into the desired number of legs, shown in the figure by the two legs 20 and 22, which are separated by a slot 24, which extends along the entire length of the shaft and thus into the body 14 to end in a larger, curved opening. 26. By providing the end of the slot 24 with a curved end 26, the possibility of cracking in the closed end of the slot 24 when compressive forces are applied to the legs 20 and 22 as will be described later is avoided.

The enlarged termination 26 / of the slot 24 not only eliminates the possibility of splicing the screw pin 10 at the end of the slot but also forms a member by means of which the legs 20 and 22 on the shaft of the pin can bend and move relative to each other so that they can pressed against each other in the radial direction. The connection between the legs 20 and 22 at the surface around the larger end 26 of the slot thus functions as a spring-like joint, around which the legs can bend and yield.

As can be seen, the slot 24 forms space for the legs 20 and 22 in their radial movements towards and away from each other. It also absorbs radial forces on the legs as they are threaded into the root canal 19 in the tooth 25. The ability of the legs to bend and move towards and away from each other gives them opportunities to adapt to irregularities in the thread 12 of the root canal.

This movement allows the legs to absorb stresses and forces that would otherwise be applied to the walls of the root canal 19 and could cause the tooth 25 to crack.

As will also be seen, the longitudinal extension of the slot 24 between the legs 20 and 22 ends at a point 26 which lies within the body 14 and provides a unique advantage over the prior art. The space in the slot 24 forms a space for debris in the tooth, which relieves hydraulic and pneumatic forces which normally have a tendency to build up under the screw pin 10 as this is threaded with cement into the root canal of the tooth. The slot 24, which allows relative movement of the legs and which is longer than the shaft 12, provides a path out from the bottom of the root canal 19 in the tooth 25 and from the insertion end of the shaft 12 up to the surrounding atmosphere. The space 24 allows the accumulation of debris, air, fluids and gases and the discharge of these from the channel 19 without damage to the tooth root.

The thread 18 on the shaft 12 extends along its entire length and along the entire length of the larger body diameter.14. The lower end 28 may be tapered or curved in the manner shown in Fig. 1 so that it can fully adhere to the tapered or curved portion of the correspondingly recessed tooth root 25 in which the shaft and body are to be threaded. Thus, when the shaft 12 and the body 14 are completely screwed into the tooth root canal 19, the tapered or curved end 28 of the body 14 will engage the inner, drilled surface of the tooth so that it fits perfectly therein without tension. The larger threaded body 14 is well fitted in the recessed crown cavity to provide a complete and larger abutment surface wall to wall for the retaining engagement. This avoids the application of external lateral forces to the engaging surface of the tooth root 25, which could otherwise crack the tooth during engagement by means of previously known screw pins.

Although it has been found in practice that the adapted shape 28 on the body 14 avoids cracking of the tooth root during the procedure, it is within the scope of the invention that an elastic washer or seal 30, as more clearly shown in Fig. 2, can be used together with the screw pin 10. The washer or seal 30 may be made of any suitable elastic or resilient material, e.g. "silastic". When the washer 30 10 15 20 25 30 35 _s 453 556 is threaded upwards along the thread 18 on the shaft 12, it stops on abutment against the underside of the body 14 adjacent to its curved or tapered surface 28.

When the shaft 12 and the body 14 are threaded into the tooth root canal 19 to their full length, the washer 30 compresses upon its engagement with the coronal side of the tooth root 25 to form an airtight seal between the tooth root and the surface 28 of the body 14. In this engagement and compression, it also absorbs shocks so that it absorbs stresses and forces which can otherwise be applied when threading the screw pin 10 into the root canal 25. After the pin 10 has been threaded into the tooth root canal 19 and a crown 31 has been manufactured and anchored around the root and crown attachment 16 on the screw pin 10, the washer 30 acts to absorb the stresses and forces applied to the crown 31 and the tooth root 25 via the screw pin 10 during chewing or other grinding movements of the tooth.

The washer or seal 30 can be excluded from the screw pin 10 in some cases when the seat and the fit between the body 14 and the root 25 are judged sufficient and suitable without it. In other circumstances, it may be desirable to include the washer 30 to provide effective sealing and force absorption.

After the screw pin 10 has been reliably threaded into the tooth root 25, it provides sufficient restoration of mass in the tooth root for the crown to be attached to the tooth root by means of the crown bracket 16. The crown bracket is generally denoted by 16 and extends beyond the tooth root in a direction opposite to the threaded shaft 12.

As the figure shows, the crown bracket 16 comprises a series or a number of truncated cones 32, which are separated from each other along the length of the screw pin 10 by means of continuous and uniform extensions or separators 34. Each truncated conical element 32 has the larger diameter of 453 ; .356 its outer, sloping surface directed towards the shaft of the screw pin, which is arranged to be threaded into the tooth root channel 19 or opposite the shaft 12.

This downward and outward direction on the tapered surfaces of the cone elements 32 reinforces the attachment of the screw pin 10.

If the height of the crown bracket 16 is greater than necessary for the crown restoration, it can shorten its length by simply grinding away as many of the truncated conical anchoring elements 32 and separators 34 as are superfluous and unnecessary.

The threaded insertion of the shaft 12 and the body 14 into the tooth root canal takes place in a self-tapping manner so that it forms a root canal thread 17, the sides of which are substantially parallel and completely correspond to the shape of the self-tapping part 18 and the outsides of the shaft 12 and the body 14 of the screw pin 10.

Tooth cement is poured into the root canal 19 and can also be applied to the shaft 12 and the body 14, so that it comes into intimate contact with all the surfaces of the thread 18.

Although the shaft is shown as divided into two legs, it is within the scope of the invention that the shaft can be divided into any number of legs and with similar valve spaces or separations 24 between them.

After cement has been added to the shaft 12 and the body 14, the whole is ready for threaded insertion into the tooth root canal 19.

In accordance with prior art methods, this has been done by hand or using a tool for screwing the screw pin 10 down along the threaded or non-threaded toothed channel. It has been found that the use of excessive torque on the screw pin 10 gives a tendency to crack the tooth if it exceeds the tooth root 10 - 15 20 25 30 35 _? 45s 356 lateral strength or the resistance of the tooth to the shaft 12 and the body 14 during threading. Therefore, it is within the inventive idea that the screw pin 10 is screwed into the tooth root channel by means of a releasable torque wrench 40 as Figs. 3 and 5 show. The key 40 has the ability to apply a torque to the pin 10 which is less than the resistance of the tooth root to cracking. Q.

The torque wrench 40 includes a manually rotatable knob 42, the interior of which is hollowed out to form a chamber 44 as shown in FIG. The lower end of the chamber terminates with a wall 46 with a centrally located opening 48 through which a drive pin 50 extends outwardly from the knob 42. The pin 50 has an enlarged head 52, the underside of which forms a coupling or engaging surfaces which can engage the opposite surface. on the wall 46. The engaging surface of the head 52 and the wall 46 form a coupling for transmitting the torque from the head 42 to the drive pin 50. The surfaces are relatively smooth and therefore allow sliding between the surfaces when desired and required.

The inner chamber 44 of the knob 42 is threaded at 54 so that it can receive a threaded adjusting element in the form of a nut 56, which in the usual way can be provided with a groove 58 for a screwdriver. Between the adjusting element 56 and the head 52 of the drive pin 50 there is a resilient member in the form of a spring 60. The spring 60 is trapped between the adjusting element 56 and the head S2 and the spring tension can be varied by adjusting the element 56 in the chamber 44 in the sleeve 42.

The interior of the key may be closed against unwanted tampering by fitting a cover 62 over the thread 54. The driven end of the pin 50 may be provided with any desired engagement means for screwing the screw pin 10 during its screwing into the tooth root channel. For the sake of clarity, it is shown with a simple screwdriver blade 64. The screw pin 10 is provided at the upper side with a corresponding engaging groove 66 to receive the blade 64. Those skilled in the art will appreciate that other cooperating arrangements may be made. 356 _ß is provided to provide the torque limiting object of the invention.

Before screwing in the screw pin 10 in the tooth root channel 19, the nut 56 on the torque wrench 40 is adjusted to compress the spring 60 so that it provides a predetermined force against the head 52 of the drive pin 50 so that it comes into surface contact with the wall 46. After adjusting the torque wrench 40 is now ready for use. The shaft 12 of the screw pin is arranged in line with the tooth root channel 19. The initial rotation of the screw pin 10 can take place by means of the fingers of the hand for inserting the screw pin and its shaft 12 into the channel 19. Thereafter the screw pin is screwed into the tooth root in a self-tapping manner. Using the torque wrench 40 by placing the blade 64 on the torque wrench in engagement with the receiving groove 66 on the screw pin 10 and rotating the knob 42.

As the shaft 12 and the body 14 gradually enter the tooth root canal 19 and form the thread 17, any liquid, debris, gases or air trapped below the insertion end of the shaft is taken up for release to the atmosphere during the self-tapping insertion as previously described to until the connection 26 is finally enclosed within the mouth of the channel 19. The resilient connection between the legs 20 and 22 allows the legs to bend inwards radially towards each other so that they adapt to and accommodate irregularities which may occur during the engagement between the threads 18. in the tooth root canal 19.

The breaking forces that can occur during the threading are absorbed in this way by the legs giving way radially inwards towards each other due to the slit 24 between them.

The connection 26, which has a memory, acts as an outwardly pressing spring to always cause the threads 18 on the shaft 12 and the body 14 to move radially outwards until full thread engagement with the threads 17, which they form in the root canal 19. This constantly guarantees fully satisfactory 10 15 20 25 30 35 9 453 356 _ thread engagement between threads 17 and 18.

When a sealing washer 30 is used as shown in Fig. 8, it is compressed between the exposed wall of the tooth root and the body 14 so that it completely seals the space between them and provides a shock absorber therebetween. When the sealing washer 30 is omitted, adjacent surface of the body 14 comes into abutment and wall sealing engagement with the recessed wall of the tooth root canal 19.

Although the tooth cement previously applied to the shaft 12 and the body 14 and its threads 18 is sufficient to retain the whole in cemented frictional engagement with the tooth root canal 19, upon curing of the cement, any tendency of the screw pin 10 to rotate out of the tooth root canal 19 later occasion prevented by the radially outwardly directed spring force against the legs 20 and 22 in the spring-like connection 26 between them. Thus, the spring-like connection 26 forms a memory which strives to return the legs 20 and 22 to full surface contact and anti-rotation engagement with the threads 17 in the tooth root canal 19.

If, when threading the shaft 12 and the body 14 in the root canal 19, resistive forces occur which exceed the force of the set spring 60 in the torque wrench 40, the spring 60 allows a relative sliding movement between the wall 46 in the knob 42 and adjacent engagement surfaces on the head 52 of the pin 50. As a result, it is not possible to continue threading? the shaft 12 and the body 14 into the root canal 19 by means of the torque wrench 42 until the resistance force between the threads 17 and 18 has disappeared or considerably decreased. Consequently, the rotation and torque against the screw pin 10 ends through the drive pin 50. No further rotation of the knob 42 can cause the screw pin 10 to thread deeper into the root channel 19 until crack-forming forces have disappeared.

From what has been described, it is clear that since adjustment of the element 56 in the torque wrench 42 has been performed so that the spring 60 does not produce a predetermined frictional engagement between the head of the drive pin 50 and the surface of the wall 46 of the knob 42 which exceeds tooth strength and crack resistance, the tooth will not crack when using the torque wrench 40.

No further rotation of the knob 42 will result in continued threading of the shaft in the tooth root 19 as the surfaces of the coupling will slide and rotate relative to each other without transmitting a force. Furthermore, although the shaft 12 and the body 14 have the ability to absorb cracking forces between the shaft and the tooth root 19, the torque wrench 40 provides guarantees that its use with the screw pin 10 will never cause such force on the tooth root 25 that exceeds the durability of the tooth root. .

After the screw pin 10 has been applied to the tooth root 25 in the manner described above, the screw pin is now ready to receive a crown 68 for the tooth root 25 against the crown bracket 16 on the screw pin 10. The crown 68 is designed in the usual way to give a precise fit to the tooth root 25. It is provided with a standard cavity, which is arranged to envelop the crown bracket 16.

The crown 68 is shown schematically in Fig. 7. Details of its design can be changed and are not necessarily limited to those shown here. Before assembling the crown 68 against the crown bracket 16, dental cement or composite cement is added to its interior. Tooth cement or composite cement can also be applied to the free surfaces of the truncated conical anchoring elements 32 and around the partitions 34 and body 14 of the screw pin 10. The multi-conically truncated crown bracket 16 is unusually well adapted for use in restoring old or previously use bridges and crowns.

It has previously been stated that the small ends of the truncated cones 32 extend in the direction away from the shaft 12 and towards the interior of the cavity in the crown 68 while the large ends of the cones 32 extend downwards towards the body 14 and the shaft 12. The undersides of the large ends of the anchoring the cones 32 act as surfaces under which the dental cement 10 15 20 25 30 35 j1 453 356. or the composite cement flows and against which it hardens during engagement. They taper as shown and described to allow natural flow of the dental cement along the narrower portions of the frustoconical anchor cones 32, along the larger surfaces and into the spaces formed by the partitions 34 between each cone member.

In practice it has been found that when the dental cement is compressed, it will flow along the path of least resistance from the small ends of the conical anchoring elements 32 towards their large ends and then into the spaces formed by the partitions 34. The application at the beginning of the dental cement in the spaces formed by means of the partitions 34 is compressed even more when the crown 68 is applied over the entire anchoring device 16. The forces applied by means of the crown cause the cement to flow into all spaces below the large ends of the truncating cones 32 to give full engagement with them. This ensures a correct and long-lasting connection and engagement between the crown 68 and the crown bracket 16 and prevents the formation of air pockets in the crown.

The embodiment of the screw pin in Fig. 4 has in its entirety the designation 110. The numbers 10 in this embodiment correspond to similar elements described in connection with the embodiment 10 in Figs. 1 and 3. For the sake of simplicity, all designations in connection with the description of the liner 110 of Fig. 4 identified in the 100 series.

Fig. 4 differs from the embodiment 10 in that it lacks the body 14. Unlike the previous embodiment, the screw pin 110 is particularly well adapted for use with multi-rooted teeth, in which two or more screw pins 110 can be used. Embodiment 110 includes a threaded, substantially parallel-sided shaft 112, the thread 118 of which extends along each of its plurality of legs 120 and 122. As in Embodiment 10, the legs are divided and spaced apart by a slot 124 which extends along a considerable length of the shaft and terminating adjacent the end 'furthest from the shaft at the enlarged, spring-like memory holding connection 126.

In the embodiment 110, the elongation of the shaft 112 is so great that its coronal end terminates at the mouth of the root canal 19. Similarly, the slot 124 provides adequate ventilation to the atmosphere from the insertion end of the shaft 112 during its self-tapping insertion into the channel 19 until the connection 126 finally lies in the root canal. The screw pin 110 is made in one piece and comprises a crown bracket 116 which is made and which operates in substantially the same way as the crown bracket 16 in the previously described embodiment 10. Therefore, a detailed repetition of the description will be omitted.

To ensure that the screw pin 110 is properly threaded into the tooth root channel 19 when applying a torque which does not exceed the strength of the tooth 25, the torque wrench 40 can be used as previously described in connection with the embodiment 10. To allow use of the key 40, the embodiment 110 is provided with a corresponding screwdriver groove 166, which is adapted to receive the screwdriver blade 64.

Those skilled in the art will appreciate that the image and description of the complementary shaped blade 64 and the notch 66 does not limit the scope of the invention. Any other complementary shaped engagement means can be used to provide the threaded engagement for screw pins according to the invention in the root canal 19 with a force which does not exceed the strength of the tooth root 25.

Fig. 6 shows an embodiment which in many essential pieces corresponds to the embodiment 10 shown in Figs. 1 and 3. Here, similar parts are identified by the same I. . tens while all designations for separation 'are numbered in the 200 series. 10 15 20 25 30 35 '13 453 556.

The similarity between the embodiment 210 and the embodiment 10 is at once clear. The shaft 212 terminates in the body 214 and both are slotted at 224 to form a plurality of legs 220 and 222, which are spaced apart by resilient movements relative to each other to absorb shocks and forces that can be applied to the threads 218 during self-tapping insertion. and the engagement between the screw pin 210 and the tooth root canal 19. As with previously described embodiments, the embodiment 210 is made in one piece which comprises a body 214 in which the wall of an enlarged opening 126 has a memory for distinguishing the legs 220 and 222. .

It also provides space for debris and for ventilation to the atmosphere from the insertion end of the shaft 212 when threading the shaft and the body in the complementary drilled part of the root 19. As shown in Fig. 6, the embodiment 210 may utilize a washer or seal 230 of the like. strokes described in the embodiment 10.

Embodiment 210 differs from Embodiment 10 in terms of details of anchor bracket 216. Embodiment 210 is unusually well adapted for use in restoring a new crown. For this reason, the crown bracket 216 eliminates the need for a plurality of relatively spaced apart anchoring elements 32 in the form of truncated cones combined into a single truncated cone 232 with a smooth surface. Its small end faces the shaft 212 while the large end faces its only connection to and extension of the body 214.

The use of the screw pin 210 takes place in substantially the same way as previously described in connection with previous embodiments. With respect to the screw pin 210, the anchoring member 232 is provided with a cutter 266, which receives the end 64 of the pin 50 of the torque wrench 40. The application and threaded insertion of the shaft 212 on the screw pin 210 in the threaded root channel 19 takes place in the same manner as previously described. using the torque wrench 40.

The blade 64 engages the groove 64 on the armature member 232 to rotate it into the toothed channel 19. If during the self-tapping retraction forces are applied to the legs of the shaft 212 which exceed the force of the spring 60 in the torque wrench 40 previously set by means of the nut 56, the coupling surfaces between the wall 46 and the head 52 will slide relative to each other. This guarantees that the moment against the screw pin can never exceed the strength of the tooth 25 or generate cracking forces on the walls of the root canal 19.

As previously described, the legs 220 and 222 will bend independently and move relative to each other as a result of forces against them during the threading process. This ability of the legs in the shaft to spring depending on the thread forces allows them to act as shock absorbers, which transmit such forces to the legs of the shaft for absorption. Without such a shock absorber, the forces act outwards against the newly threaded wall of the tooth root canal 19 and can crack the tooth 25 if the forces exceed the strength of the tooth.

In each of the embodiments, the many legs are usually separated from each other by slits between the legs. In each case, the legs spring relative to each other for forces directed towards them to adapt to irregularities in the self-tapping movement along the tooth root canal 19. In each case, the spring connection from the walls around the larger opening 26, 126 and 226 at the far end restorative force against the legs to cause them to regain their normal parallelism. This outwardly directed force at the spring connection 26 brings the threads 18 on the screw pins more completely into engagement with the complementary surfaces of the formed threads 17 in the tooth root canal 19. The spring action of the legs allows them to absorb stresses along the entire length and the slotted part of the body. . This provides better co-operation and retention between the screw pin and the shaped threads 17 in the tooth 25; This improved engagement also prevents unscrewing and possible loss of the screw pin from the tooth root channel 19 and at the same time provides complete shock absorption between them. Various changes in shape and detail of the device shown and described may be made by those skilled in the art without departing from the scope of the invention. The invention is limited only by the appended claims.

Claims (9)

10 15 25 30 35 453 356 16 Patent claims 1. l. Screw pin for insertion into a tooth root canal and comprising a substantially cylindrical, threaded shaft (12) for screwing into the tooth root canal (19). characterized in that the shaft (12) is substantially cylindrical from the insertion end over the entire length of the shaft (12), that at least one slot (24) in the shaft (12) extends from the insertion end a considerable distance for dividing the shaft (12) into a number of threaded legs (20, 22), separated by slots (24), so that the legs (20, 22) can move relative to each other to absorb crack-generating forces which occur against the legs when the shaft is screwed in (12) in the tooth root canal (19). it is true that the shaft (12) carries a means (16) for anchoring a dental crown. Screw pin according to claim 1, characterized in that the anchoring member (16) forms part of the screw pin and extends away from the insertion end of the shaft (12) and comprises a number of spaced apart, stylized conical elements (32), the diameter of which decreases. in the direction away from the shaft (12). Screw pin according to claim 1, characterized in that a threaded body (14) is arranged between the shaft (12) and the anchoring member (16) and has a larger diameter than the shaft (12). Screw pin according to claim 3, characterized in that the body (14) adjacent to the shaft (12) is rounded to prevent cracking of the tooth during engagement with the tooth when the shaft (12) and the body (14) are pushed in. 5. Screw pin according to claim 3, characterized by a shock-absorbing member (30) arranged between the body (14) and the shaft (12) and compressible between the body (14) and the tooth root when the shaft (12) and the body (14) become threaded for 10 15 20 453 356 17 absorption of forces between them. Screw pin according to claim 3, characterized in that the slot (24) extends past the shaft (12) and into the body (14) and ends with an enlarged one. curved opening (26) in the body (14). which prevents cracking of the body (14) at the end of the slot (24) and strengthens the relative movement of the legs (20, 22). Screw pin according to claim 3, characterized in that the anchoring member is a frustoconical extension (216) of the body (214) opposite the shaft (212) and with a larger diameter than the body (214). Screw pin according to claim 1, characterized in that the anchoring member (116) consists of mutually separated truncated cones (132). Screw pin according to claim 1, characterized in that the gap (24) between the legs (20, 22) extends from the end of the threaded shaft (12) to provide ventilation to the atmosphere to prevent the build-up of forces in the tooth root canal ( 19) at the insertion end of the shaft.