JP2021023776A - Surgical guide and water flow pipe therefor, and molding method for surgical guide - Google Patents

Abstract

To securely guide cooling water to a part to be bored, with a simple configuration.SOLUTION: A surgical guide 2 to be mounted in an oral cavity has a water flow pipe 4 for externally guiding a cooling liquid to a living body part to be bored inside the surgical guide. The water flow pipe 4 is disposed so that its inside end part 4A opens in the vicinity of a lower edge 3UE of a sleeve 3 provided on the surgical guide 2 and faces the part AB1 to be bored and its outside end part 4B extends outwardly from the surgical guide 2. The water flow pipe 4 is disposed in a radial direction with respect to an axis core O1 of the sleeve 3 and is provided in an inclined state. The outside end part 4B of the water flow pipe 4 is connected to a cooling liquid supply mechanism 6 for sending the cooling liquid to the surgical guide 2 in synchronization with an operation of a drill, where the cooling liquid is guided to the part AB1 to be bored only when the drill operates.SELECTED DRAWING: Figure 5

Description

The present invention relates to a surgical guide used in dental surgery such as implant surgery, a water pipe thereof, and a method for molding the surgical guide.

In recent years, an implant placement guide system for implanting an implant in an ideal position in dental implant treatment has been provided. This implant placement guide system simulates the implant placement position in advance based on the CT data of the patient's jawbone treatment site, and drills the drilling position and drilling so that the implant can be placed as planned. A surgical guide for determining the depth is created, and implant surgery is performed using it.

Conventionally, in such a drilling method using a surgical guide, for example, a sleeve having an inner diameter substantially the same as that of a drill is provided in the surgical guide, the drill is inserted into the sleeve, and the blade portion is rotated at high speed to drill a living bone. Such a method is known (see, for example, Patent Document 1).

Further, in order to prevent the occurrence of bone burns due to the high-speed rotation of the drill blade when using the drill, a drilling system is known in which a water injection mechanism is provided inside the drill to inject water into the rotating blade to cool the drill. (See, for example, Patent Document 2). Further, it is known that a water supply port for supplying water or physiological saline as cooling water is provided in the center of the head of the implant handpiece to be inserted into the guide hole of the surgical guide (for example, patent). Reference 3).

Japanese Patent Application Laid-Open No. 2007-511275 JP 2013-244390 JP-A-2009-165799

The drilling system described in Patent Document 2 has a problem that not only the mechanism of the drill becomes complicated and costly, but also the drill becomes heavier and longer, and the operability deteriorates. Further, in the drilling system described in Patent Document 3, not only the structure of the handpiece is complicated, but also the water supply port is provided at the upper end of the drill bar, so that the drilling portion covered with the surgical guide when the drill is used. There is a problem that it is not clear whether the cooling water is surely reaching the drill bar. Further, if bone fragments or tissues are clogged in the cooling water outlet, there is a problem that the cooling performance is deteriorated.

The present invention has been made to solve the above problems, and firstly, it is an object of the present invention to provide a surgical guide capable of reliably ensuring cooling performance with a simple configuration. Secondly, it is an object of the present invention to provide a highly versatile surgical guide water pipe that can be applied to an existing surgical guide. A third object of the present invention is to provide a method for molding a surgical guide, which can integrally mold a water pipe at the time of molding the surgical guide to simplify the process and reduce the cost.

The surgical guide according to the present invention is characterized in that the surgical guide mounted in the oral cavity is provided with a water passage means for guiding the cooling liquid from the outside to a site to be perforated in the living body in the surgical guide.

In the surgical guide according to the present invention, the surgical guide mounted in the oral cavity is provided with a water passage means for guiding the cooling liquid from the outside to the planned biological perforation site in the surgical guide, so that the discharge port of the water passage means is provided. It can be arranged in advance in a part that requires cooling that cannot be seen from the outside, and the cooling performance can be reliably ensured.

Further, in the surgical guide according to the above invention, the surgical guide is provided with a sleeve to which the blade portion of the drill is guided, and one end of the water passage means is opened near the lower edge of the sleeve to face the planned drilling portion. It is preferably composed of a water pipe whose end extends from the surgical guide. With such a configuration, one end of the water pipe can always supply the cooling liquid toward the blade portion of the drill. Further, since the other end of the water pipe extends from the surgical guide, it is easy to connect to the tube for supplying the supply liquid. Further, in the surgical guide according to the above invention, it is preferable that the water pipe is arranged in the radial direction with respect to the axis of the sleeve. With such a configuration, the coolant can be supplied toward the shaft core of the blade portion. Further, in the surgical guide according to the above invention, it is preferable that the water pipe is composed of a hard pipe body, and the other end is connected to a coolant supply means for feeding the coolant to the surgical guide in synchronization with the operation of the drill. .. With such a configuration, the operation of the drill and the supply of the coolant can be synchronized, and the coolant can be efficiently supplied.

The water pipe according to the present invention is a water pipe provided in a surgical guide mounted in the oral cavity, and is characterized in that the coolant is guided from the outside to a site to be perforated in the living body in the surgical guide.

The water pipe according to the present invention is a water pipe provided in a surgical guide mounted in the oral cavity, and the cooling liquid is guided from the outside to a site where a biological perforation is planned in the surgical guide. It can be arranged corresponding to the drilling site in the surgical guide without going through a drill, and the cooling water can be guided reliably and efficiently. In addition, since the water pipe can be retrofitted to the existing surgical guide, versatility can be improved.

The method for molding a surgical guide according to the present invention is a method for molding a surgical guide to be mounted in the oral cavity by molding a synthetic resin, and at the time of molding, a coolant is applied from the outside into the surgical guide. It is characterized by integrally molding a water pipe that leads to the planned site for perforation of the living body.

The method for molding a surgical guide according to the present invention is a method for molding a surgical guide in which a surgical guide to be mounted in the oral cavity is formed by molding a synthetic resin. At the time of molding, a coolant is applied from the outside into the surgical guide. By integrally molding the water pipe that leads to the planned site for perforation of the living body, the process can be simplified and the cost can be reduced.

Further, in the method for molding a surgical guide according to the above invention, it is preferable to insert a water pipe into the surgical guide after molding the surgical guide. With such a configuration, the water pipe can be arranged so as to correspond to the perforated portion in the surgical guide, and the cooling water can be guided reliably and efficiently. In addition, since the water pipe can be retrofitted to the existing surgical guide, versatility can be improved.

In the surgical guide according to the present invention, the surgical guide mounted in the oral cavity is provided with a water passage means for guiding the coolant from the outside to the planned biological perforation site in the surgical guide, so that the cooling performance can be reliably performed with a simple configuration. Can be secured.

The water pipe according to the present invention is a water pipe provided in the surgical guide mounted in the oral cavity, and the coolant is guided from the outside to the planned biological perforation site in the surgical guide, so that it is reliable and efficient. Cooling water can be guided. In addition, since the water pipe can be retrofitted to the existing surgical guide, versatility can be improved.

The method for molding a surgical guide according to the present invention is a method for molding a surgical guide in which a surgical guide to be mounted in the oral cavity is formed by molding a synthetic resin. At the time of molding, a coolant is applied from the outside into the surgical guide. Since the water pipe leading to the planned site for perforation of the living body is integrally molded, the process can be simplified and the cost can be reduced.

FIG. 1 is a rear perspective view showing a surgical guide according to an embodiment of the present invention. FIG. 2 is an explanatory view showing the back surface of the surgical guide of FIG. FIG. 3 is a perspective view of the surgical guide of FIG. 1 as viewed from the side. FIG. 4 is an enlarged bottom view showing a main part of the surgical guide of FIG. 1. FIG. 5 is a cross-sectional view showing a cross section of a main part of the surgical guide of FIG. FIG. 6 is an explanatory view showing a state in which the surgical guide of FIG. 1 is attached to the lower teeth of the oral cavity.

Hereinafter, the present invention will be described with reference to one embodiment shown in the drawings. The surgical guide 2 according to an embodiment of the present invention is to be mounted in the oral cavity, and as shown in FIGS. 1 to 3, the surgical guide 2 is previously used for implant surgery based on the CT data of the mandibular treatment site of the patient. It is made of synthetic resin made to simulate the implant placement position and determine the drilling position and drilling depth so that the implant can be placed as planned.

The surgical guide 2 has a stainless steel sleeve 3 (in the case of this embodiment, 3A, 3B, 3C,) having an inner diameter on which a drill (not shown) can slide at a site corresponding to the perforation position of the mandibular treatment site. (4 in 3D) are provided so that the shaft core O1 is aligned with the drilling center O2. A drill bit (not shown) is guided to the sleeve 3 from above.

By the way, in the surgical guide 2 according to the present embodiment, as shown in FIGS. 4 and 5, the coolant injected at the time of perforation is injected from the outside into the mandibular treatment site (living body perforation site) AB in the surgical guide 2. (Alveolar Bone) 1 is provided with a water pipe (water passage means) 4 leading to the first. The water pipe 4 is composed of a straight stainless steel pipe having a diameter of about 1 mm, the inner end portion 4A is opened near the lower edge 3UE of the sleeve 3 and faces the planned drilling portion AB1, and the outer end portion 4B at the other end is. It extends from the surgical guide 2. These water pipes 4 are provided for each sleeve 3. With this configuration, the cooling liquid can always be supplied from the inner end portion 4A of the water pipe 4 toward the blade portion of the drill. Further, since the outer end portion 4B of the water pipe 4 extends from the surgical guide 2, it is easy to connect to the irrigation tube 5 that supplies the supply liquid.

The water pipe 4 is arranged in the radial direction with respect to the shaft core O1 of the sleeve 3 and is provided so as to be inclined. That is, the coolant can be supplied from the radial direction and at an angle inclined with respect to the axis of the rotating blade portion (not shown) of the drill. With such a configuration, the coolant can be reliably supplied toward the shaft core of the blade portion. 1 to 5 show an example applied when the surgical guide 2 is attached to the lower dentition, and the inner end portion 4A of the water pipe 4 opens downward and is inclined from the surgical guide 2. The outer end portion 4B extending outward is opened upward, but it goes without saying that when the surgical guide is attached to the upper dentition, both the sleeve 3 and the water pipe 4 are upside down. No.

Further, the water pipe 4 is connected to the pump P controlled by the control device C via the irrigation tube 5, and the pump P is connected to the coolant supply source R. The coolant supply mechanism (coolant supply means) 6 is configured by the irrigation tube 5, the control device C, the pump P, and the coolant supply source R. In the coolant supply mechanism 6, the control device C drives the pump P in synchronization with the operation of a drill (not shown), and supplies the coolant to the planned drilling portion AB1 of the surgical guide 2 through the water pipe 4 during the drill operation. It has become. The coolant introduced into the oral cavity through the water pipe 4 is removed by the practitioner at the time of surgery through an appropriate suction / drainage device. With such a configuration, the operation of the drill and the supply of the coolant can be synchronized, and the coolant can be efficiently supplied.

As shown in FIGS. 1 and 3, the outer end 4B of each water pipe 4 provided on the surgical guide 2 for each sleeve 3 is aligned toward the front side. That is, when the surgical guide 2 is placed in the patient's oral cavity, when the mouth is opened, the surgical guides 2 are arranged side by side in substantially the same direction. Therefore, each water pipe 4 has a length L1 (for example, about 10 mm) of the water pipe 4 provided on the sleeves 3B and 3C on the front side of the practitioner and sleeves 3A and 3D on the back side of the practitioner. The length L2 (for example, about 30 mm) of the provided water pipe 4 is made different (L1 <L2). With such a configuration, the practitioner connects the irrigation tube 5 from the front side of the patient to the aligned outer end 4B of the water pipe 4, which facilitates the connection. On the other hand, in the case of the back teeth side, for example, when the sleeve 3 is provided in the maxillary second molar, it is difficult to insert from the front, so a hole is made from the palate side and the outer end 4B of the water pipe 4 is placed in the palate. It may be arranged on the outside or on the outside.

Next, the operation of the surgical guide 2 according to the above embodiment will be described. The surgical guide 2 according to the above embodiment is first attached to the oral cavity of a patient. At this time, the outer end portions 4B of each water pipe 4 are arranged so as to face the front side. Next, the irrigation tube of the coolant supply mechanism 6 is connected to the outer end portion 4B of the water pipe 4 corresponding to the sleeve 3B of the planned drilling portion AB1. Then, at the time of surgery, when the blade of the drill is inserted into the sleeve 3B and the drill is driven, the coolant supply mechanism 6 operates in synchronization with the drive of the drill, and the coolant is supplied from the pump P to the water pipe 4 through the irrigation tube 5. Is supplied, the coolant is discharged from the inner end portion 4A of the water pipe 4 toward the blade portion, and the coolant is accurately guided from a position close to the drilling portion AB1. Therefore, it can be arranged in advance in a portion that requires cooling that cannot be seen from the outside, and the coolant is surely guided to the perforated portion AB1. Further, since the coolant supply mechanism 6 guides the coolant through a path independent of the drill, the structure of the drill can be simplified and the cost can be reduced.

Next, a method of molding the surgical guide 2 according to the above embodiment will be described. In the molding method of the surgical guide 2 according to the above embodiment, when molding with synthetic resin, the water pipe 4 is arranged near the hole in which the inner end 4A is mounted, and the vicinity of the lower edge 3UE of the sleeve 3. The outer end portion 4B at the other end is integrally molded so as to extend outward from the surgical guide 2 so as to face the planned drilling portion AB1. With such a configuration, the process can be simplified and the cost can be reduced.

Further, in the method of molding the surgical guide according to another embodiment of the present invention, in the above embodiment, the water pipe 4 is integrally molded with the surgical guide 2 at the time of surgical guide molding, whereas first, the surgical guide is molded. After molding the guide and molding the surgical guide, the water pipe 14 is arranged at the inner end 14A near the hole where the sleeve 3 is mounted, and is opened near the lower edge 3UE of the sleeve 3 to be drilled. A hole is formed in the surgical guide so that the outer end portion 14B at the other end extends outward from the surgical guide 2, and the water pipe 14 is inserted into the hole. With this configuration, the water pipe 14 can be arranged so as to correspond to the perforated portion in the surgical guide 12 after molding, and the degree of freedom of arrangement can be improved. Therefore, the cooling water can be reliably and efficiently guided. Further, since the water pipe 14 can be retrofitted to the existing surgical guide 22, versatility can be improved. That is, since the water pipe 14 according to the present invention can be freely retrofitted to the existing surgical guide 22, the degree of freedom of arrangement is widened and the cost can be reduced.

In the above embodiment, the water pipe 4 is made of stainless steel, but the present invention is not limited to this, and any rigid metal body may be used, or a hard plastic (synthetic). It may be composed of a tube (made of resin). Further, when connecting the water pipe 4 to the irrigation tube 5, an adapter may be used to facilitate the connection. Further, in the above embodiment, the water passage means is composed of the water pipe 4, but the present invention is not limited to this, and the surgical guide is opened in the vicinity of the lower edge 3UE of the sleeve 3 to face the planned drilling portion AB1. , The outer end is composed of a hole drilled so as to open to the outer surface of the surgical guide, a connector is provided in the outer opening of this hole, and the connector is connected to the irrigation tube 5 of the coolant supply mechanism 6 via the connector. You may do so. Further, instead of the water pipe 4, the water passage means is composed of a needle having a cooling water supply port formed at the tip, a coolant passage formed inside, and an outer end connectable to the coolant supply mechanism 6. The needle may be press-fitted into the surgical guide 12 after molding or the existing surgical guide 22.

2 Surgical guide 4 Water pipe (water flow means)
AB1 Expected site for perforation of the living body

Claims (7)

A surgical guide that is mounted in the oral cavity and is provided with a water passage means that guides a coolant from the outside to a site to be perforated in the living body in the surgical guide. The surgical guide is provided with a sleeve that guides the blade of the drill.
The surgical guide according to claim 1, wherein one end of the water passage means is opened near the lower edge of the sleeve to face a portion to be drilled, and the other end is composed of a water pipe extending from the surgical guide. .. The surgical guide according to claim 2, wherein the water pipe is arranged in the radial direction with respect to the axis of the sleeve. The surgical guide according to claim 3, wherein the water pipe is composed of a rigid pipe body, and the other end is connected to a coolant supply means for feeding the coolant to the surgical guide in synchronization with the operation of the drill. .. A water pipe provided in a surgical guide mounted in the oral cavity, characterized in that a coolant is guided from the outside to a site where a biological perforation is planned in the surgical guide. It is a method of molding a surgical guide that forms a surgical guide to be mounted in the oral cavity by molding a synthetic resin. During molding, a water pipe that guides the coolant from the outside to the planned biological perforation site in the surgical guide is integrated. A method of molding a surgical guide, which is characterized by being molded. The method for molding a surgical guide according to claim 6, wherein the water pipe is inserted into the surgical guide after molding the surgical guide.