KR101027579B1 - Maxillary bone reamer for lifting safety maxillary sinus - Google Patents

Abstract

The present invention is a bone tissue dilator for safe maxillary sinus elevation that can be easily and conveniently expanded in a clean and safe state without damaging the maxillary sinus membrane using the bone tissue dilator in the perforated portion of the maxilla for implant placement during dental implant procedures Regarding, the bone tissue expander of the present invention is formed in the shape of the device body 22 is formed in a shape that is larger in diameter from the upper outer peripheral surface to the lower outer peripheral surface, the maxillary sinus membrane is formed on the upper end of the device body 22 The head 24 having a round (R) shape to prevent damage to the maxillary sinus membrane 30 in contact with the 30 and the upper outer peripheral surface of the device body 22 are formed at an interval of 120 ° and the device body ( It characterized in that it consists of a water supply hole 28, the end is branched in three directions while passing through the support pole 40 and the device body 22 formed at the lower end of the 22.

Implant procedure, Maxillary sinus elevation, Bone expander, Head, Watering hole, Recessed groove, Stopper

Description

Maxillary bone reamer for lifting safety maxillary sinus

The present invention relates to a bone tissue dilator for safe maxillary sinus elevation, and more particularly, using a perforated portion of the maxilla for bone implantation during dental implant surgery without damaging the maxillary sinus membrane. It's easy and easy to extend from.

In general, an implant (or implant) originally means a substitute that recovers when the tissue of the human body is lost, but in the dentist, it means an artificial tooth implant, which is rejected by the human body to replace the root of the missing tooth. An artificial tooth root made of titanium, which is not reacted, is planted in the alveolar bone where the tooth is drained and then bonded to fix the artificial tooth so that the original function of the tooth can be restored.In the case of general prosthetics or dentures, the teeth and bones around Although it is virtual, the implant has the great advantage of not damaging the surrounding tooth tissue, and similar in function or shape to natural teeth, but does not cause tooth decay.

In order to perform the above-described implant, first, the gingival of the patient to be implanted is exposed to expose the alveolar bone, and then the position of the implant to be inserted among the exposed alveolar bone is determined, and then a drilling tool such as a drill is used at the position. After drilling a predetermined position of the alveolar bone to form a hole for implantation, the implant procedure is completed by placing the implant in the formed hole and covering the gingival.

In particular, it is reported that the implant success rate in the maxillary posterior portion is relatively low compared to other sites during the implantation procedure, because the maxillary sinus is weak in the maxillary posterior region and the maxillary sinus cannot be embedded in the long implant.

In other words, the maxillary sinus present in the maxilla is a space surrounded by the mucosa, and when the tooth is lost physiologically, it descends downwards and expands. This is because the amount of bone in the bone is insufficient and the implantation in the maxillary posterior region is difficult.

On the other hand, in the case of lack of bone mass to the maxillary sinus, a typical method of treatment is to form a side hole (window) below the cheekbone and directly elevate the maxillary sinus membrane to fill the implant between the maxillary sinus and the maxillary sinus membrane. When expanding the perforated portion of the maxilla for implant placement, the perforated region is first expanded using a small diameter drill, and then the perforated region is finally expanded while using a drill with a larger diameter.

However, in the conventional drills for implants, which are used in order from the smallest to smallest in diameter, the drill tip is in contact with the maxillary sinus membrane as soon as the maxillary perforation is completed by the rotation of the drill blade. Since there is no structure to prevent the maxillary sinus from being torn or rolled up by the tip of the drill, it is difficult for even experienced dentists to replace the drill in such a way that it is difficult to treat the maxillary sinus. There was a demand for the emergence of a device that can be easily and simply expanded in a clean and safe state without this occurrence.

Therefore, the present invention has been made in order to solve the above-mentioned conventional problems, the present invention cleans without damaging the maxillary sinus membrane using a bone tissue expansion machine in the perforated portion of the maxilla for implant placement during dental implants It is easy and easy to expand in a safe and safe state, so that the patient can be treated in a comfortable state, and the bone tissue dilator for safe maxillary sinus elevation that can shorten the healing period by minimizing the pain that the patient feels before and after implant placement. The purpose is to provide.

In order to achieve the above object, the present invention is equipped with a cutting edge on the outer peripheral surface of the device body to enlarge the perforated portion of the maxilla for implant placement as it is mechanically vibrated to receive the electrical vibration is mounted on the hand piece of the main unit of the creation And a bone tissue expander having a support pole extending from the lower end of the device body, the device body being formed in a shape in which the diameter increases from the upper outer circumferential surface to the lower outer circumferential surface, and formed on the upper end of the upper body. The head has a round shape to prevent damage to the maxillary sinus membrane during contact with the maxillary sinus membrane, and is formed at 120 ° intervals on the upper outer circumferential surface of the apparatus body and passes through a support pole formed at the bottom of the instrument body and the instrument body. Safe maxillary sinus, characterized in that consisting of a water supply hole branching in three directions A bone tissue expander is provided for the injury.

In addition, the water supply hole is characterized in that formed in the center of the upper end of the head through the support pole and the device body.

In addition, a space is formed between the upper outer peripheral surface of the device body and the lower end of the head.

And, the upper outer peripheral surface of the support pole is characterized in that the stopper for limiting the insertion depth of the device body is formed integrally protruding when expanding the perforated portion of the maxilla.

As described above, the present invention can be easily and conveniently expanded in a clean and safe state without damaging the maxillary sinus membrane using the bone tissue dilatation device for the perforation of the maxilla for implant placement during dental implant procedures. In addition to being able to be treated in a comfortable state, it is a very useful invention that greatly improves the efficiency and reliability of the device because it can shorten the healing period by minimizing the pain felt by the patient before and after implant placement.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention for achieving the above object will be described in detail.

1 is an overall front view showing a first embodiment of a bone tissue dilator for maxillary sinus elevation of the present invention, Figures 2a to 2c is an operating state when expanding the puncture site of the maxilla using the bone tissue dilator of the present invention 3 is a front view showing a second embodiment of the present invention, FIG. 4 is a front view showing a third embodiment of the present invention, and FIG. 5 is a front view showing a fourth embodiment of the present invention. to be.

The present invention is mounted on the handpiece of the main unit (not shown) to enlarge the perforated portion 12 of the maxilla 10 for implant placement during dental implant procedure, as the power is applied to the main unit The device body 22 of the bone tissue expander 20 which is mechanically vibrated by receiving electrical vibration is formed in a shape that increases in diameter from the upper outer circumferential surface to the lower outer circumferential surface. In order to prevent damage to the maxillary sinus membrane 30 when the maxillary sinus membrane 30 is contacted, a head 24 having a round (R) shape is formed.

In addition, a cutting edge 26 having a lattice shape protrudes from the entire outer circumferential surface of the device body 22, and is formed at the lower end of the device body 22 on the upper outer circumferential surface of the device body 22. Water supply holes 28 are formed at intervals of 120 ° while penetrating through the support pole 40 and the device body 22 in three directions.

In addition, the upper outer peripheral surface of the support pole 40 is formed so that the stopper 50 for limiting the insertion depth of the device body 22 is integrally protruded when the perforated part 12 of the maxillary bone 10 is enlarged. .

At this time, the stopper 50 of the present invention can be manufactured and used in a form that is not formed in the support pole 40 as necessary.

The present invention configured as described above is shown in Figure 2a to 2c, by implanting the implant during the dental implant procedure using the bone tissue dilator 20 which is mechanically vibrated by receiving the electrical vibration generated in the main body of the creation In order to enlarge the perforated part 12 of the maxilla 10, first, the support pole 40 of the bone tissue expander 20 is mounted on the hand piece driving unit of the main body of the bone tissue expander when power is applied ( In the state in which 20 is ready for immediate operation, the head 24 formed on the upper part of the device body 22 of the bone tissue expander 20 approaches the puncture portion 12 of the maxilla 10 as shown in FIG. 2A. do.

Subsequently, in the state as illustrated in FIG. 2A, the end of the lattice-shaped cutting edge 26 protruding from the entire outer circumferential surface of the device body 22 by a dentist applied by the operator is a perforated part of the maxilla 10. 12), and then, when the bone tissue expander 20 is operated by applying power to the hand piece, as shown in FIG. 2B, the cutting edge 26 of the device body 22 is the maxillary bone ( At the same time as it is inserted into the perforated portion 12 of the 10) and at the same time, formed on the upper outer peripheral surface of the device body 22 at 120 ° intervals and the support pole 40 and the device body formed at the bottom of the device body 22 The cutting edge 26 is cut while maintaining the clean circumference of the perforated part 12 of the maxilla 10 while spraying water through the water supply hole 28 through which the end branches in three directions while penetrating the 22. Accordingly, the perforation part 12 of the maxilla 10 can be effectively expanded. It is.

In addition, in order to be expanded throughout the perforated part 12 of the maxilla 10, the instrument body 22 of the bone tissue expander 20 must completely penetrate the existing perforated part 12, Since the head 24 formed on the upper part of the device body 22 of the present invention has a smooth round R shape, the maxillary sinus membrane 30 is formed from the moment when the head 24 contacts the maxillary sinus membrane 30. Since the device body 22 completely penetrates the puncturing portion 12 as shown in FIG. 2C, the maxillary sinus membrane 50 can be torn or damaged.

In addition, since the stopper 50 is integrally formed on the upper outer circumferential surface of the support pole 40, the device body 22 is excessively inserted when the perforated part 12 of the maxilla 10 is enlarged. It can be prevented.

Meanwhile, as a second embodiment of the present invention, as shown in FIG. 3, the water supply hole 28 may be formed in the center of the upper end of the head 24 through the support pole 40 and the device body 22. In addition, as shown in FIGS. 4 and 5 as the third and fourth embodiments of the present invention, a shape between the outer peripheral surface of the upper end of the device body 22 and the lower end of the head 24 of the bone tissue expander 20 is not in close contact. By forming the empty space portion S, the maxillary sinus in the gap between the upper outer peripheral surface of the device body 22 and the lower end of the head 24 due to the space portion S when the perforation portion 12 of the maxilla 10 is enlarged. The membrane 30 may be prevented from being torn or directly contacted in advance, thereby preventing the maxillary sinus membrane 30 from being damaged.

Embodiment of the bone tissue expander of the present invention described above is merely illustrative, and those skilled in the art to which the present invention pertains well that various modifications and equivalent other embodiments are possible from this. Could be. Therefore, it is to be understood that the present invention is not limited to the specific forms mentioned in the above description. Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims, and the present invention is intended to cover all modifications, equivalents, and substitutes within the spirit and scope of the present invention as defined by the appended claims. It should be understood to include.

1 is an overall front view showing a first embodiment of a bone tissue dilator for maxillary sinus elevation of the present invention

Figure 2a to 2c is a longitudinal sectional view sequentially showing the operating state when expanding the puncture site of the maxilla using the bone tissue dilator of the present invention

3 is a front view showing a second embodiment of the present invention;

4 is a front view showing a third embodiment of the present invention.

5 is a front view showing a fourth embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10; Maxilla 12; Perforation area

20; Bone tissue dilator 22; Instrument body

24; Head 26; Cutting edge

28; Water supply hole 30; Maxillary sinus

40; Support pole 50; Stopper

R; Round S; Space

Claims (4)

A cutting edge is formed on the outer circumferential surface of the device body in order to enlarge the perforated portion of the maxilla for implant placement as it is mounted on the hand piece of the main device and receives electrical vibration and mechanically vibrates, and is supported on the bottom of the device body. In the bone tissue expander in which the pole is extended, A device body 22 formed in a shape in which the diameter increases from the upper outer circumferential surface to the lower outer circumferential surface; A head 24 formed at an upper end of the device body 22 and having a round (R) shape to prevent damage to the maxillary sinus membrane 30 in contact with the maxillary sinus membrane 30 for elevation of the maxillary sinus, Water supply holes 28 formed on the upper outer circumferential surface of the device body 22 at intervals of 120 ° and having end portions branched in three directions while passing through the support pole 40 and the device body 22 formed at the bottom of the device body 22. Bone tissue dilator for safe maxillary sinus elevation, characterized in that consisting of. 2. The bone tissue expander for safe maxillary sinus elevation according to claim 1, characterized in that the water supply hole (28) is formed in the center of the upper end of the head (24) through the support pole (40) and the device body (22). 2. The bone tissue expander for safe maxillary sinus elevation according to claim 1, wherein a space (S) is formed between the upper outer peripheral surface of the device body (22) and the lower end of the head (24). According to claim 1, The upper outer peripheral surface of the support pole 40, the stopper 50 for limiting the insertion depth of the device body 22 is formed integrally protruding when the perforated part 12 of the maxilla 10 Bone tissue dilator for safe maxillary sinus elevation.

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