KR100611946B1 - Stent for implant - Google Patents

Abstract

An implant stent is disclosed. Implant stent of the present invention, the drill receiving hole to at least partially wrap the drill forming a hole in the alveolar bone, the guide for guiding the drilling direction of the drill; And a rod protruding from one side of the guide in the transverse direction with respect to the axis of the drill receiving hole and coupled to an impression body of the tooth disposed adjacent to the tooth to be implanted to support the guide. According to the present invention, it is easy to use, which facilitates the implant procedure, shortens the implant procedure time, and makes the implant procedure accurate and safe.

Description

Stent for Implants {STENT FOR IMPLANT}

1 is a perspective view of a stent for an implant according to an embodiment of the present invention.

2 is a view showing an example of an oral cavity to be implanted.

Figure 3 is a side cross-sectional view showing the main use state of the implant stent of FIG.

4 is a perspective view of a stent for an implant according to another embodiment of the present invention.

5 is an exploded perspective view of FIG. 4.

6 is a side cross-sectional view showing main parts of the implanted stent of FIG. 4.

           * Explanation of symbols for the main parts of the drawings

      3: tooth 5: alveolar bone

   7,7 ': hole 11: drill

     15: impression body 20, 20 ': stent for implant

 21,21 ': Guide 25,25': Drillman

 31,31 ': Load 35: Scale

    35 ': marking line 41: shaft

     43: shaft body 45: scale

     47: rod coupling portion 49: through hole

     51: screw hole 55: set screw

The present invention relates to an implant stent, and more particularly to an implant stent that can be implanted in the alveolar bone more accurately and safely.

Implants are originally meant to be a substitute for recovery when tissue is lost, but in dentistry, implants are made of artificial teeth. In order to replace the lost root (root), a tooth root made of titanium (titanium), which is not rejected by the human body, is planted in the alveolar bone where the tooth falls out, and the artificial tooth is fixed to restore the function of the tooth. In the case of general prosthetics or dentures, the surrounding teeth and bones are damaged after time, but the implants do not damage the surrounding dental tissues.

The artificial tooth procedure is completed by drilling a placement position using a predetermined drill, placing the implant in the alveolar bone, fusion fusion to the bone, joining the abutment to the implant, and then applying the final prosthesis to the abutment. .

These implants enhance the function of dentures, improve the aesthetics of dental prosthetic restorations, as well as dissipate excessive stress on surrounding supportive bone tissue, as well as single missing restorations. And also helps stabilize the dentition.

On the other hand, since the implant is placed after drilling the alveolar bone of the patient using a drill or the like, the drilling operation of the alveolar bone is the most important.

Thus, a stent is used to implant the implant. The stent is used to find the exact placement of the patient's teeth prior to implant placement. The stent is inserted and fixed to adjacent teeth.

Here, the process of implanting an implant using a conventional stent will be briefly described as follows.

First, using the impression material made of rubber material, the patient's upper and lower mandibular shapes (lifts) are obtained, and plaster is poured onto the obtained impression body to produce a plaster model identical to the upper and lower mandibles of the patient.

Subsequently, the plaster model is coupled to the articulator to reproduce the interrelationship of the jaw joint and the upper and lower teeth, which are almost similar to the patient's condition, outside the mouth.

Next, a model of the tooth to be joined to the site where the tooth is lost is used and the model is used as a stent.

The central part of the artificial tooth model formed on the stent is the position where the implant is placed, and when the hole is formed for the drill, the stent is completed. In particular, the conventional stent is manufactured to be inserted into the peripheral tooth is fixed by inserting in the teeth. The number and location of implants to be placed are determined by comprehensive consideration of the patient's oral condition and X-ray results.

When the stent is completed, the patient's gingival is dissected and the stent is inserted into the remaining teeth.

Then, the position to be punctured is displayed on a suitable portion of the upper surface of the patient's alveolar bone with reference to the position of the hole punched in the stent, and a hole is formed by inserting a drill from the top of the hole of the stent and drilling the marked portion.

On the other hand, during the drilling of the alveolar bone, the scale of the drill is confirmed on the surface of the alveolar bone, and the perforation portion on the alveolar bone is located deep inside the oral cavity so that the field of view is narrow and not accessible, and the bleeding generated during the procedure covers the alveolar bone. If the scale of the operator is not easy to check.

However, in the conventional implant procedure, as described above, since the model of the tooth to be joined to the site where the tooth is lost and the model is used as a stent, it is not easy to check the scale of the drill and is excessively drilled or inaccurate. If it is punctured at the location, or not as deep as the operator thinks, there is a problem of complications or re-puncture.

In addition, in the case of drilling using a conventional implant stent, since the operator is likely to move out of the intended range, X-ray imaging or X-ray imaging to check the perforation direction of the alveolar bone during the procedure, or damage of surrounding major structures and Because of the cumbersome work to check whether there is a possibility, there is a problem that the implant procedure takes a long time and causes inconvenience to the patients.

Accordingly, it is an object of the present invention to provide an implant stent that can be easily used to facilitate the implant procedure, shorten the implant procedure time, and can accurately and safely perform the implant procedure.

According to the present invention, the guide forming a drill receiving hole at least partially surrounding the drill forming a hole in the alveolar bone, the guide for guiding the drilling direction of the drill; And a rod for protruding from one side of the guide in a transverse direction with respect to the axis of the drill receiving hole and coupled to an impression body of a tooth disposed adjacent to the tooth to be implanted to support the guide. Is achieved by.

Here, the guide and the rod is preferably made of metal so as to determine the position during X-ray imaging.

In addition, the thickness of the rod may be 0.5mm to 1.0mm for bending and cutting during the procedure.

By forming a plurality of scales along the lengthwise direction of the rod on the outer periphery of the rod, it is possible to easily adjust the position of the drill hole corresponding to the implantation position of the implant.

In addition, the rod protrudes from the upper end of one side of the guide, so if the distance from the rod to the lower end of the guide is too long to interfere with the surroundings, for example, if the alveolar bone and the lower end of the guide cause interference By rotating the guide 180 degrees around its central axis to the impression body, the distance from the rod to the bottom of the guide can be set short.

In addition, according to the present invention, the shaft coupled to the hole formed in the alveolar bone adjacent to the tooth to be implanted; A guide for forming a drill receiving hole at least partially surrounding a drill forming a hole in the alveolar bone, the guide guiding a drilling direction of the drill; And a rod protruding from one side of the guide in a transverse direction with respect to the axis of the drill receiving hole, the rod being detachably coupled to the shaft to support the guide.

Here, the rod is preferably substantially rectangular in cross section so as to prevent relative rotation with respect to the shaft when coupled to the shaft.

In addition, the rod protrudes from the upper end of one side of the guide, so if the distance from the rod to the lower end of the guide is too long to interfere with the surroundings, for example, if the alveolar bone and the lower end of the guide cause interference The distance from the rod to the bottom of the guide can be set short by rotating the guide 180 degrees around the central axis to the shaft.

At least one marking line is formed on the outer circumference of the rod along the longitudinal direction of the rod.

It is preferable that the shaft has a through hole through which the rod is coupled, and the shaft and the rod are fixed by a set screw.

By forming a plurality of scales along the longitudinal direction of the shaft on the outer circumference of the shaft, it is possible to easily check the installation height of the guide from the alveolar bone.

On the other hand, it is preferable that the length of the rod protrudes into the shaft when combined with one side of the rod in contact with the shaft to prevent interference with the adjacent teeth during the procedure is 0.001mm to 2mm.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

Prior to the description, in various embodiments, components having the same configuration will be representatively described in one embodiment using the same reference numerals, and in other embodiments, only the configuration different from the embodiment will be described.

1 is a perspective view of an implant stent according to an embodiment of the present invention, Figure 2 is a view showing an example of the oral cavity to be implanted, Figure 3 is a main portion side showing the state of use of the implant stent of Figure 1 It is a cross section. As shown in these drawings, the implant stent 20 according to an embodiment of the present invention, the guide 21 for guiding the drilling direction of the drill 11 forming the hole 7 in the alveolar bone 5 And a rod 31 which supports the guide 21 and is coupled to the impression body 15 of the tooth 3 (see FIG. 3) disposed adjacent to the tooth to be implanted.

The guide 21 has a rectangular block shape, and the guide 21 has a drill receiving hole 25 partially covering the drill 11 forming the hole 7 in the alveolar bone 5. The drill receiving hole 25 has a partial arc cross-sectional shape in which one side of the guide 21 is opened so that the drill 11 can be mounted. The diameter of the drill receiving hole 25 is formed to correspond to the diameter of the drill because almost all of the drills used are the same. That is, approximately 3 mm in diameter.

The rod 31 has a rectangular bar shape and protrudes from one side of the guide 21 in the transverse direction with respect to the axis of the drill receiving hole 25. In this case, the rod 31 protrudes from an upper end of one side of the guide 21. That is, the distances from the rod 31 to the upper end and the lower end of the guide are different. This is because if the distance from the rod 31 to the lower end of the guide 21 is too long to interfere with the surroundings, for example, if the alveolar bone 5 and the lower end of the guide 21 interfere with the rod 31. In order to prevent the interference by shortening the distance from the rod 31 to the lower end of the guide 21 by coupling the guide 21 to the impression body 15 by rotating the guide 21 by a central axis.

Since the oral cavity is narrow, bending and cutting are necessary in some cases when the rod 31 is coupled to the impression body 15. Therefore, the thickness of the rod 31 is provided as thin as 0.7 mm for bending and cutting during the procedure. .

The rod 31 in this embodiment is approximately perpendicular to the axis of the drill hole 25 (see FIG. 1). In addition, a plurality of scales 35 are formed on the outer circumference of the rod 31 along the longitudinal direction of the rod 31. The scale 35 of the rod 31 in this embodiment has a notched shape, and is formed at regular intervals. In this way, it corresponds to the implantation position of the implant, it is possible to easily adjust the coupling position of the impression body 15 and the rod 31.

On the other hand, both the guide 21 and the rod 31 are made of metal so that the position at the time of X-ray imaging can be grasped. Therefore, it is possible to know the direction and depth of the implant stent 20 according to an embodiment of the present invention and to measure and confirm an accurate drill point.

By this configuration, using the implant stent 20 according to an embodiment of the present invention, briefly described the process of drilling the hole 7 in the alveolar bone 5 as shown in FIG. same.

First, in order to implant the implant in the missing tooth of the oral cavity, the implant placement position in the alveolar bone (5) is confirmed.

Next, using the impression material made of rubber material, as shown in FIG. 5, the impression body 15 for the teeth 3 in the region adjacent to the tooth to be implanted is formed.

Subsequently, before the impression 15 is hardened, the rod 31 is engaged with the impression 15 so that interference with the tooth 3 surrounded by the impression 15 does not occur. At this time, the rod 31 is coupled to the impression body 15 so that the drill receiving hole 25 faces the alveolar bone 5. Then, the coupling position of the impression member 15 and the rod 31 is adjusted so that the drill receiving hole 25 is positioned on the implantation position of the implant.

Then, when the impression body 15 is taken, the position of the implant placement position and the drill accommodation hole 25 is reconfirmed, that is, the position of the implant placement position and the drill accommodation hole 25 is corrected.

Subsequently, the impression body 15 equipped with the guide 21 and the rod 31 is reinserted into the tooth 3 of the patient, and then the drill 11 is inserted into the drill accommodation hole 25 to insert the alveolar bone to be implanted ( Hole 7 is drilled in 5). At this time, since the outer periphery of the drill 11 is surrounded by the drill receiving hole 25 and perforated, the shaking of the drill 11 is reduced during the drilling, so that the drilling can be performed at the correct position. In addition, the practitioner can check the drilling depth of the drill (11) with the naked eye to make a perforation.

As such, a rod 21 is provided to guide the drilling direction of the drill 11, and supports the guide 21 and is coupled to the impression body 15 of the tooth 3 disposed adjacent to the tooth to be implanted. By providing (31), it is easy to use, which facilitates the implant procedure, shortens the implant procedure time, and makes the implant procedure accurate and safe.

Meanwhile, FIGS. 4 and 5 show an implant stent 20 'according to another embodiment of the present invention. The implant stent 20 'according to another embodiment of the present invention forms a drill receiving hole 25' at least partially surrounding the drill 11 forming the hole 7 'in the alveolar bone 5 11, the guide 21 'for guiding the drilling direction of the drill hole, and protrudes from one side of the guide 21' in the horizontal direction with respect to the axis of the drill receiving hole 25 'to support the guide 21', A rod 31 ′ detachably coupled to 41 and a shaft 41 coupled to a first hole 7 formed in the alveolar bone 5 adjacent to the tooth to be implanted.

One marking line 35 'is formed on the outer circumference of the rod 31' along the longitudinal direction of the rod 31 '. The marking line 35 'of the rod 31' is processed by a laser. This marking line 35 'is used to confirm the position where the rod 31' is coupled to the shaft 41 during the procedure. For example, the end of the rod 31 'is matched with the end of the rod engaging portion 47, which will be described later, or the end of the marking line 35' of the rod 31 'depends on the drilling position. The rod 31 ′ may be coupled to the shaft 41 in a state where the end portion of the rod 31 is aligned with the end of the rod 31 ′.

The rod 31 ′ also has a substantially square cross-sectional area to prevent relative rotation about the shaft 41 when coupled to the shaft 41. And when the rod 31 'protrudes from the upper end of one side of the shaft 41, and the distance from the rod 31' to the lower end of the guide 21 'is too long to cause interference with the surroundings, for example, the alveolar bone (See 5, FIG. 3) and the lower end of the guide 21 'by causing the rod 31 by rotating the gas shaft 41 by 180 degrees around the rod 31' to the shaft 41, ') From the lower end of the shaft 41 can be set short.

Meanwhile, the length of the rod 31 'protruding into the shaft 41 is 2 mm or less when the side of the rod 31' is in contact with the shaft 41 to prevent interference with adjacent teeth during the procedure. .

The shaft 41 has a circular pipe-shaped shaft body 43 and a rod coupling portion 47 provided at one end of the shaft body 43 to which the rod 31 'is penetrated.

The shaft body 43 is erected in the first hole 7 formed in the alveolar bone 5 adjacent to the tooth to be implanted. On the outer circumference of the shaft body 43, a plurality of scales 45 are formed along the longitudinal direction. The scale 45 of the shaft body 43 in this embodiment has a notched shape, and is formed at regular intervals. Thus, the installation height of the guide 21 from the alveolar bone 5 can be easily confirmed.

The rod coupling portion 47 has a rectangular block shape and is provided at an upper end of the shaft body 43. The rod coupling portion 47 is formed with a through hole 49 through which the rod 31 'passes. The through hole 49 is perpendicular to the axis of the shaft body 43. The upper end of the rod coupling portion 47 is formed with a screw hole 51 in communication with the through hole 49. The screw hole 51 is coupled to the set screw 55 for fixing the rod 31 'to be penetrated through the through hole 49.

Meanwhile, in the above-described embodiment, the rod coupling portion 47 to which the rod 31 ′ is coupled to the shaft 41 is described. However, as another example, the rod coupling portion 47 is provided on the shaft 41. Instead, the through hole 49 may be formed in the shaft body 43, so that the rod 47 may be directly coupled to the through hole 49 of the shaft body 43.

By such a configuration, for example, when a plurality of missing teeth are continuously formed in the oral cavity, a process of drilling holes 7 and 7 'in the alveolar bone 5 will be briefly described as follows. same.

First, as shown in FIG. 6, the first hole 7 is drilled in the alveolar bone 5 in the state in which the implant stent 20 according to the embodiment of the present invention is installed in the impression body 15. Then, the shaft body 43 of the implant stent 20 'according to another embodiment of the present invention in the drill hole 25 of the guide 21 of the implant stent 20 supported by the impression body 15 At the same time it is coupled to the first hole (7) of the perforated alveolar bone (5). At this time, through the plurality of scales 45 formed on the outer periphery of the shaft body 43 to check the installation height of the guide 21 'from the alveolar bone 5, the shaft body 43 of the alveolar bone 5 perforated It is coupled to the first hole (7).

Then, the rod 31 'of the implant stent 20' according to another embodiment of the present invention is coupled to the through hole 49 of the rod coupling portion 47. At this time, the drill hole 25 'of the guide 21' is coupled to the through hole 49 of the rod coupling portion 47 so that the drill hole 25 'faces the alveolar bone 5, and then the second hole 7 After adjusting the engagement position of the rod coupling portion 47 and the rod 31 'so that the drill receiving hole 25' is positioned on the position where the '' will be formed, the rod 31 'is loaded with the set screw 55. It is fixed to the coupling part 47. Thus, the implant stent 20 'for implanting the implant is completed.

Subsequently, the drill 11 is inserted through the drill accommodation hole 25 'of the guide 21' supported by the shaft 41 to drill the second hole 7 'in the alveolar bone 5. At this time, the outer periphery of the drill 11 is surrounded by the drill receiving hole (25 '), so that the perforation of the drill 11 during the drilling is reduced, so that it can be drilled in the correct position. In addition, the practitioner can check the drilling depth of the drill (11) with the naked eye to make a perforation.

This makes it possible to puncture in the correct position even when a plurality of teeth to be implanted are continuously arranged.

On the other hand, in the above embodiments, it is described that the drill receiving hole has a partial arc cross-sectional shape, the drill receiving hole may have a circular cross-sectional shape formed through the plate surface of the block in the vertical direction.

In addition, in the above-described embodiments, while the rod is described as being perpendicular to the axis of the drill hole, the rod may have a predetermined angle with the axis of the drill hole.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

As described above, according to the present invention, it is easy to use, which facilitates the implant procedure, shortens the implant procedure time, and makes the implant procedure accurate and safe.

Claims (12)

A guide for forming a drill receiving hole at least partially surrounding a drill forming a hole in the alveolar bone, the guide guiding a drilling direction of the drill; And An implant stent, comprising: a rod protruding from one side of the guide in a transverse direction with respect to the axis of the drill receiving hole and coupled to an impression body of a tooth disposed adjacent to the tooth to be implanted to support the guide. The method of claim 1, The guide and the rod, an implant stent, characterized in that made of metal so as to determine the position during X-ray (X-Ray) imaging. The method of claim 1, The thickness of the rod is an implant stent, characterized in that 0.5mm to 1.0mm for bending and cutting during the procedure. The method of claim 1, Implant stent, characterized in that a plurality of scales are formed in the outer circumference of the rod along the longitudinal direction of the rod. The method of claim 1, The rod is a stent for the implant, characterized in that protruding from the upper end of one side of the guide. A shaft coupled to a hole formed in the alveolar bone adjacent to the tooth to be implanted; A guide for forming a drill receiving hole at least partially surrounding a drill forming a hole in the alveolar bone, the guide guiding a drilling direction of the drill; And And a rod protruding from one side of the guide in a horizontal direction with respect to the axis of the drill receiving hole, the rod being detachably coupled to the shaft to support the guide. The method of claim 6, And said rod is substantially rectangular in cross-sectional area to prevent relative rotation with respect to said shaft when coupled to said shaft. The method of claim 6, The rod is a stent for the implant, characterized in that protruding from the upper end of one side of the guide. The method of claim 6, Implant stent, characterized in that the outer periphery of the rod is formed with at least one marking line in the longitudinal direction of the rod. The method of claim 6, The shaft is formed with a through hole through which the rod is coupled, the shaft and the rod is implanted stent, characterized in that fixed by a set screw. The method of claim 6, Implant stent, characterized in that a plurality of scales are formed in the outer circumference of the shaft along the longitudinal direction of the shaft. The method of claim 6, Implant stent, characterized in that the length of the rod protrudes to the shaft when combined with one side of the rod in contact with the shaft to prevent interference with adjacent teeth during the procedure.

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